Scroll compressor

ABSTRACT

A scroll compressor has an electric motor portion, a compression mechanism portion connected to the electric motor portion, and an oil sump for lubricating oil in a sealed container and compresses a refrigerant in the compression mechanism portion. A used refrigerant is a halogenated hydrocarbon or a hydrocarbon having a carbon double bond in the composition or is a mixture containing one of the same. A sliding surface of at least one of two components constituting a sliding portion having a relation of sliding to each other in a sealed container is structured in such a way that an iron metal or an aluminum metal is not directly exposed.

This is a Continuation of application Ser. No. 12/992,151 filed Nov. 11,2010, which is a National Phase of International Application No.PCT/JP2009/060782, filed on Jun. 12, 2009, which claims the benefit ofJapanese Application No. 2008-156743 filed Jun. 16, 2008. The disclosureof the prior applications is hereby incorporated by reference herein intheir entirety.

TECHNICAL FIELD

The present invention relates to a scroll compressor for use in arefrigeration air-conditioner, and more particularly to a scrollcompressor that compresses a refrigerant which is a halogenatedhydrocarbon or a hydrocarbon each having a carbon double bond in thecomposition thereof or a mixture containing thereof.

BACKGROUND ART

As measures against global warming in recent years, the inventors haveexamined a scroll compressor that uses a refrigerant having a low,so-called, global warming potential (GWP). It has been graduallyrevealed that using a refrigerant which is a halogenated hydrocarbon ora hydrocarbon each having a carbon double bond in the compositionthereof or a mixture containing thereof is promising as measures againstglobal warming.

Heretofore, there is a literature in which R1270 (propylene) ismentioned as a refrigerant (e.g., Patent Literature 1). However, it isdescribed as an example of hydrocarbons together with other hydrocarbonsnot having a double bond and is not mentioned as an example of thehalogenated hydrocarbon or the hydrocarbon each having a carbon doublebond in the composition thereof.

CITATION LIST Patent Literature

-   PTL 1: Japanese Unexamined Patent Application Publication No.    2000-274360

SUMMARY OF INVENTION Technical Problem

The halogenated hydrocarbon or hydrocarbon having a carbon double bondin the composition has a tendency that thermal or chemical stability islikely to decrease to cause decomposition or polymerization comparedwith a composition having no double bond. Therefore, a technique forcontrolling the occurrence of a chemical reaction of the refrigerant isrequired. In general, for polymerization of hydrocarbons, a hightemperature and high pressure environment and catalyst such as metalsfor accelerating a chemical reaction are used. In the inside of thescroll compressor, conditions corresponding to the above is easily madeby each sliding portion in which iron metal or aluminum metal isexposed. Therefore, when the refrigerant which is a halogenatedhydrocarbon or a hydrocarbon having a carbon double bond in thecomposition or a mixture containing thereof is used, the followingproblems arise.

More specifically, in the sliding portion of the scroll compressor withwhich the refrigerant may contact, the double bond of the halogenatedhydrocarbon or hydrocarbon having the carbon double bond in thecomposition is decomposed or polymerized and generates sludge, whichdeteriorates the sliding state of the compressor or blocks a compressiontube portion of a capillary tube or the like in a refrigeration circuit,and thus the reliability of the refrigeration air-conditioner maydecrease.

The invention has been made in order to solve the above-describedproblems. It is an object of the invention to provide a high-reliabilityscroll compressor capable of suppressing the occurrence of decompositionor polymerization due to the chemical reaction of the refrigerant evenwhen the refrigerant which is a halogenated hydrocarbon or a hydrocarbonhaving a carbon double bond in the composition or a mixture containingthereof is used.

Solution to Problem

A scroll compressor of the invention has, in a sealed container, anelectric motor portion, a compression mechanism portion connected to theelectric motor portion, and an oil sump for lubricating oil andcompresses a refrigerant in the compression mechanism portion. In thescroll compressor, the refrigerant to be used is a halogenatedhydrocarbon or a hydrocarbon each having a carbon double bond in thecomposition thereof or is a mixture containing either one of thehalogenated hydrocarbon or the hydrocarbon. A sliding surface of atleast either one of two components constituting a sliding portion inwhich the two components are slidable to each other in the sealedcontainer is structured so that iron metal or aluminum metal is notdirectly exposed. Specifically, materials of the corresponding portionsare formed with non-metal materials, such as ceramics or resin, or thecorresponding portions are subjected to coating treatment or filmformation treatment.

Advantageous Effects of Invention

In order to suppress decomposition or polymerization due to a chemicalreaction in a sliding portion in the compressor of the refrigerant whichis a halogenated hydrocarbon or a hydrocarbon each having a carbondouble bond in the composition thereof, the scroll compressor of theinvention is structured so that the iron metal or the aluminum metalthat can serve as a metal catalyst that promotes the chemical reactionis not directly exposed to the slide surface of the sliding portion inthe compressor. Therefore, even in the sliding portion of the scrollcompressor in which the temperature and the pressure are likely toincrease, the decomposition or polymerization of the refrigerant issuppressed, and thus the generation of sludge is suppressed to suppresstroubles of the compressor or blocking in a refrigeration circuit, whichallows obtaining reliability over a long period of time of thecompressor.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a structure diagram showing the structure of a scrollcompressor according to Embodiment 1 of the invention.

FIG. 2 is an explanatory view of a sliding portion containing a swingscroll and a thrust plate in the compressor of the aspect of FIG. 1.

FIG. 3 is an explanatory view of a sliding portion containing the swingscroll and a fixed scroll in the compressor of the aspect of FIG. 1.

FIG. 4 is an explanatory view of a sliding portion containing the swingscroll and a seal and the fixed scroll and a seal in the compressor ofthe aspect of FIG. 1.

FIG. 5 is an explanatory view of a sliding portion containing the swingscroll and an Oldham ring and the Oldham ring and a frame in thecompressor of the aspect of FIG. 1.

FIG. 6 is an explanatory view of a sliding portion containing the swingscroll and a slider and the slider and a main axis in the compressor ofthe aspect of FIG. 1.

FIG. 7 is an explanatory view of a sliding portion containing the frameand a sleeve and the sleeve and the main axis in the compressor of theaspect of FIG. 1.

FIG. 8 is an explanatory view of a sliding portion containing a sliderplate that enters a slider and a main axis of a scroll compressor ofEmbodiment 2 of the invention.

FIG. 9 is an explanatory view showing the sliding state of a slidingportion to which each element of FIG. 8 is attached.

FIG. 10 is a cross sectional view showing the inside of a scrollcompressor in Embodiment 3 of the invention.

FIG. 11 is an explanatory view of a sliding portion containing a swingscroll and an Oldham ring and a fixed scroll and an Oldham ring in thecompressor of the aspect of FIG. 10.

FIG. 12 is an explanatory view of the sliding portion containing athrust bearing member provided at the swing scroll and the thrust platein the compressor of the aspect of FIG. 10.

FIG. 13 is a structure diagram showing the structure of a scrollcompressor according to Embodiment 4 of the invention.

FIG. 14 is an explanatory view of a sliding portion containing a thrustplate provided at a swing scroll and a thrust bearing member provided ata frame in the compressor of the aspect of FIG. 13.

FIG. 15 is a structure diagram showing the structure of a scrollcompressor according to Embodiment 5 of the invention.

FIG. 16 is an explanatory view of a compression mechanism portion in thecompressor of the aspect of FIG. 15.

FIG. 17 is a cross sectional view showing the inside of the scrollcompressor according to Embodiment 6 of the invention.

FIG. 18 is a cross sectional view showing the inside of the scrollcompressor according to Embodiment 7 of the invention.

DESCRIPTION OF EMBODIMENTS

A refrigerant to be used in a scroll compressor of the embodiment of theinvention is as follows.

(1) Halogenated hydrocarbon having a carbon double bond in thecomposition thereof: For example, “HFO-1234yf (CF₃CF═CH₂)” in which theglobal warming potential (GWP) is as low as about 4 is mentioned.

The “HFO” is the abbreviation for “Hydro-Fluoro-Olefin” and the “Olefin”refers to an unsaturated hydrocarbon having one double bond.

(2) Hydrocarbon having a carbon double bond in the composition thereof:For example, “R1270 (propylene)” is mentioned. The “R1270” has a GWP ofabout 3, which is smaller than the GWP of the “HFO-1234yf” but theinflammability is higher than that of the “HFO-1234yf”.(3) A mixture containing at least either one of the halogenatedhydrocarbon or the hydrocarbon each having a carbon double bond in thecomposition thereof: For example, a mixture of the “HFO-1234yf” and“R32” or “R41” is mentioned. The pressure loss of the “HFO-1234yf”becomes larger due to a low-pressure refrigerant and the performance ofthe “HFO-1234yf” is likely to decrease in a refrigeration cycle.Therefore, mixtures of the “HFO-1234yf” and the “R32”, the “R41”, or thelike, which is a high-pressure refrigerant whose pressure is higher thanthat of the “HFO-1234yf” are preferable for practical use.

The embodiments of the invention will be successively described below onthe assumption of the use of the refrigerants described above. In eachdrawing, the same elements or the equivalents are designated by the samereference numerals.

Embodiment 1

FIG. 1 is a structure diagram showing the structure of a scrollcompressor according to Embodiment 1 of the invention. The scrollcompressor has a fixed scroll 1, a swing scroll 2, a frame 3 that fixesthe fixed scroll 1, a main bearing 4 positioned at the center of theframe 3, and a swing bearing positioned at the center of the swingscroll 2. The scroll compressor further has a thrust plate 6 serving asa thrust bearing that supports the swing scroll 2 in the axis direction,an Oldham ring 7 that prevents rotation of the swing scroll 2 andapplies swing movement thereto, and an electric motor rotor 8 and anelectric motor stator 9 that constitute an electric motor.

The scroll compressor further has a main axis 10 that is rotated anddriven by the electric motor, a slider 11 that supports the swing scroll2 in order to revolve the swing scroll 2, and a decentrated slider axis10 a, serving as a slider attachment axis, which is provided at theupper portion of the main axis 10 so that the slider 11 is decentratedrelative to the main axis 10. The scroll compressor further has a sleeve12 that is positioned near the decentrated slider axis 10 a and smoothlyrotates the main bearing 4 positioned at the center of the frame 3 andbalancers 13 and 14 that cancel unbalance of the rotation center of theswing scroll 2 that swings by the decentrated slider axis 10 a of themain axis 10 and the main axis 10.

A sub-frame 15 is provided at a lower portion in the axis direction ofthe main axis 10 and the outer ring of a ball bearing 16 is press-fittedto a bearing storage portion 15 a that is formed at the center of thesub-frame 15. The sub-frame 15 has a volume controlled oil pump 18 and apump axis 10 b that transmits rotational force to the oil pump 18 isintegrally molded with the main axis 10. An oil hole 10 c thatpenetrates from the lower end of the pump axis 10 b to the upper end ofthe main axis 10 is formed at the center of the main axis 10 and the oilhole 10 c communicates with the oil pump 18 at the lower end side.

A sealed container 20 that accommodates the respective elements containsthree portions of a sealed container trunk portion 20 a, a sealedcontainer lower portion 20 b, and a sealed container upper portion 20 c.At the upper stage of the sealed container trunk portion 20 a, acompressor mechanism portion containing the fixed scroll 1, the swingscroll 2, the frame 3, etc., is disposed and an inhalation pipe 21 fortaking a refrigerant into the container is also provided. At the lowerstage of the sealed container trunk portion 20 c, the electric motorrotor 8 or the electric motor stator 9 are disposed. At the sealedcontainer lower portion 20 b, the oil sump 19 is formed. At the sealedcontainer upper portion 20 c, a discharge pipe 22 that discharges acompressed refrigerant to the outside of the container is provided.

FIG. 2 is an explanatory view of a sliding portion containing the swingscroll 2 and the thrust plate 6 in the compressor of the aspect ofFIG. 1. The thrust plate 6 serves as the thrust bearing that supportsthe swing scroll 2 in the axis direction. The swing scroll 2 and thethrust plate 6 are slidable to each other and constitute the slidingportion. More specifically, a thrust bearing portion 2 h is formed atthe back surface (surface opposite to the surface having a spiral shape)of the swing scroll 2 and is adhered to a slide surface 6 a of thethrust plate 6 through lubricating oil and constitute the thrustbearing.

The swing scroll 2 is formed with iron metal, such as cast iron, or anAl—Si alloy metal and the surface of the swing scroll 2 including thethrust bearing portion 2 h is subjected to coating of any one of DLC(diamond-like carbon), DLC-Si (diamond-like carbon silicon), CrN(chromium nitride), TiN (titanium nitride), TiCN (titaniumcarbonitride), WCC (tungsten carbide coating), VC (vanadium carbide),etc., or film formation treatment of any one of a manganese phosphatefilm, a molybdenum disulfide film, etc. The thrust plate 6 is formedwith iron metal or aluminum metal and the surface of the thrust plate 6including the slide surface 6 a is subjected to coating of any one ofDLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., or film formation treatmentof any one of a manganese phosphate film, a molybdenum disulfide film,etc.

FIG. 3 is an explanatory view of a sliding portion containing the swingscroll 2 and the fixed scroll 1 in the compressor of the aspect ofFIG. 1. A lap portion 2 a that constitutes the spiral shape of the swingscroll 2 and a lap portion 1 a that constitutes the spiral shape of thefixed scroll 1 are slidable to each other and constitute the slidingportion. More specifically, the lap portion 2 a formed in the spiralshape substantially perpendicular to a panel 2 b of the swing scroll 2and the lap portion 1 a formed in the spiral shape substantiallyperpendicular to a panel 1 b of the fixed scroll 1 are adhered to eachother through lubricating oil to constitute a compression chamber 23.

The lap portion 2 a of the swing scroll 2 is formed with iron metal,such as cast iron, or an Al—Si alloy metal, which is the same materialas that of the swing scroll 2. However, the surface of the swing scroll2 including a side surface 2 d of the lap portion 2 a is subjected tocoating of any one of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., orfilm formation treatment of any one of a molybdenum disulfide film, amanganese phosphate film, etc.

The lap portion 1 a of the fixed scroll 1 is formed with iron metal,such as cast iron, or an Al—Si alloy metal that is the same material asthat of the fixed scroll 1. However, the surface of the fixed scroll 1including a side surface 1 d of the lap portion 1 a is subjected tocoating of any one of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., orfilm formation treatment of a manganese phosphate film, a molybdenumdisulfide film, etc.

FIG. 4 is an explanatory view of a sliding portion containing the swingscroll 2 and a seal provided at the top end surface of the lap portionof the fixed scroll 1 and the fixed scroll and a seal provided at thetop end surface of the lap portion of the swing scroll 2 in thecompressor of the aspect of FIG. 1.

In order to reduce the leak of a refrigerant from the top end surface ofeach of the lap portions 1 a and 2 a when the lap portion 2 a of theswing scroll 2 and the lap portion 1 a of the fixed scroll 1 are adheredto each other through lubricating oil to constitute the compressionchamber 23, seals 24 and 25 are provided in grooves provided at the topend surfaces thereof in accordance with the spiral shape. The seal 24 isprovided at the top end surface of the lap portion 1 a of the fixedscroll 1. The seal 24 portion and a bottom land 2 e at the side of thelap portion 2 a of the panel 2 b of the swing scroll 2 are slidable toeach other and constitute the sliding portion. The seal 25 is providedat the top end surface of the lap portion 2 a of the swing scroll 2. Theseal 25 portion and a bottom land 1 e at the side of the lap portion 1 aof the panel 1 b of the fixed scroll 1 are slidable to each other andconstitute the sliding portion. These seals 24 and 25 are formed withnon-metal materials, such as PTFE (polytetrafluoroethylene), PPS(polyphenylene sulfide), LCP (liquid crystal polymer), or ceramics.

The bottom land 1 e of the fixed scroll 1 is formed with iron metal,such as cast iron, or an Al—Si alloy metal, which is the same materialas that of the fixed scroll 1. However, the surface of the fixed scroll1 including the bottom land 1 e of the fixed scroll 1 is subjected tocoating of any one of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., orfilm formation treatment of any one of a manganese phosphate film, amolybdenum disulfide film, etc.

The bottom land 2 e of the swing scroll 2 is formed with iron metal,such as cast iron, or an Al—Si alloy metal, which is the same materialas that of the swing scroll 2. However, the surface of the swing scroll2 including the bottom land 2 e of the swing scroll 2 is subjected tocoating of any one of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., orfilm formation treatment of any one of a manganese phosphate film, amolybdenum disulfide film, etc.

FIG. 5 is an explanatory view of a sliding portion containing the swingscroll 2 and the Oldham ring 7, and the Oldham ring 7 and the frame 3 inthe compressor of the aspect of FIG. 1.

Oldham grooves 2 f provided in the back surface opposite to the sidewhere the lap portion 2 a of the mirror panel 2 b of the swing scroll 2is formed and upper convex portions 7 a that are keys of the Oldham ring7 are in a relation to be slidable to each other and constitute thesliding portion. Oldham grooves 3 f provided near the main bearing 4 ofthe frame 3 and lower convex portions 7 b that are keys of the Oldhamring 7 are in a relation to be slidable to each other and constitute thesliding portion. More specifically, the back surface opposite to theside the lap portion 2 a of the panel 2 b of the swing scroll 2 isformed has the Oldham grooves 2 f that accommodate the upper convexportions 7 a of the Oldham ring 7 to slide the same so as to prevent therotation of the swing scroll 2 to apply swing movement to the swingscroll 2 d.

The Oldham grooves 2 f are formed with iron metal, such as cast iron, oran Al—Si alloy metal, which is the same material as that of the swingscroll 2. However, the surface of the swing scroll 2 including theOldham grooves 2 f of the swing scroll 2 is subjected to coating of anyone of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., or film formationtreatment of any one of a manganese phosphate film, a molybdenumdisulfide film, etc.

Moreover, by providing the Oldham grooves 3 f in the frame 3 to befastened to the fixed scroll 1 and accommodating the lower convexportions 7 b of the Oldham ring 7, the swing scroll 2 can swing relativeto the fixed scroll 1.

The Oldham grooves 3 f of the frame 3 are formed with iron metal, suchas cast iron, which is the same material as that of the frame 3.However, the surface of the frame 3 including the Oldham grooves of theframe 3 is subjected to coating of any one of DLC, DLC-Si, CrN, TiN,TiCN, WCC, VC, etc., or film formation treatment of any one of amanganese phosphate film, a molybdenum disulfide film, etc.

The respective convex portions 7 a and 7 b of the Oldham ring 7 areformed with high-rigidity and lightweight materials, such as iron metal,such as sintering, or an aluminum alloy metal, which is the samematerial as that of the Oldham ring 7. However, the surface of theOldham ring 7 including the respective convex portions 7 a and 7 b issubjected to coating of any one of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC,etc., or film formation treatment of any one of a manganese phosphatefilm, a molybdenum disulfide film, etc.

FIG. 6 is an explanatory view of the sliding portion containing theswing scroll 2 and a slider 11 and the slider 11 and the main axis 10 inthe compressor of the aspect of FIG. 1.

The inner circumference of the swing bearing 5 provided at the center ofthe back surface opposite to the side of the panel 2 b of the swingscroll 2 on which the lap portion 2 a is formed and the outercircumference of the slider 11 that is decentrated relative to therotation center of the main axis 10 and drives the swing axis areslidable to each other and constitute the sliding portion. Moreover, thedecentrated slider axis 10 a to which the slider 11 is attached and aslide surface 11 a inside the slider 11 are slidable to each other andconstitute the sliding portion. More specifically, the slider 11 isaccommodated inside the swing bearing 5, and then the innercircumference of the swing bearing 5 and the outer circumference of theslider 11 are adhered to each other through lubricating oil toconstitute the swing bearing portion. The decentrated slider axis 10 aof the main axis 10 is inserted into the slider 11. To the slide surface11 a inside the slider 11 through lubricating oil, a first pivot portion10 d that is provided substantially at the center of the plane portionof the decentrated slider axis 10 a is adhered. The first pivot portion10 d is a portion projected from the plane portion in an approximatelycircular shape or an approximately spherical shape.

For the inner circumferential surface of the swing bearing 5, anon-metal bearing containing PTFE, POM (polyacetal), carbon, etc., asthe main ingredients, is used. The slider 11 is formed withhigh-hardness iron metal, such as sintering or alloy tool steel.However, the outer circumferential surface of the slider 11 or thesurface of the slider 11 including the slide surface 11 a is subjectedto coating of any one of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., orfilm formation treatment of any one of a manganese phosphate film, amolybdenum disulfide film, etc.

The first pivot portion 10 d is formed with iron metal, such as castiron or alloy steel for machine structures, which is the same materialas that the main axis 10. However, the surface of the main axis 10including the first pivot portion 10 d is subjected to coating of anyone of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., or film formationtreatment of any one of a manganese phosphate film, a molybdenumdisulfide film, etc.

FIG. 7 is an explanatory view of the sliding portion containing theframe 3 and a sleeve 12, and the sleeve 12 and the main axis 10 in thecompressor of the aspect of FIG. 1.

The inner circumference of the frame bearing 4 provided at the center ofthe frame 3 and the outer circumference of the sleeve 12 are in arelation to be slidable to each other and constitute the slidingportion. An inner circumference side 12 a of the sleeve 12 and a secondpivot portion 10 e of the main axis 10 are in a relation to be slidableto each other and constitute the sliding portion. More specifically, thesleeve 12 is accommodated inside the frame bearing 4, and the innercircumference of the frame bearing 4 and the outer circumference of thesleeve 12 are adhered to each other through lubricating oil toconstitute a main bearing portion. The main axis 10 is inserted insidethe sleeve 12, and the inner circumference side 12 a inside the sleeve12 and the second pivot portion 10 e of the main axis 10 are adhered toeach other through lubricating oil. The second pivot portion 10 e isprojected from the cylindrical surface in an approximately circularshape or an approximately spherical shape.

For the inner circumferential surface of the frame bearing 4, anon-metal bearing containing PTFE, POM, carbon, etc., as the mainingredients is used. The sleeve 12 is formed by high-hardness iron metalsuch as sintering or alloy tool steel. However, the surface of thesleeve 12 including the outer circumference or the inner circumferentialsurface 12 a of the sleeve 12 is subjected to coating by any one of DLC,DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., or film formation treatment ofany one of a manganese phosphate film, a molybdenum disulfide film, etc.The second pivot portion 10 e of the main axis 10 is formed by ironmetal such as cast iron or alloy steel for machine structural use, whichis the same material as that of the main axis 10. However, the surfaceof the main axis 10 including the second pivot portion 10 e of the mainaxis 10 is subjected to coating of any one of DLC, DLC-Si, CrN, TiN,TiCN, WCC, VC, etc., or film formation treatment of any one of amanganese phosphate film, a molybdenum disulfide film, etc.

Next, the operation of the scroll compressor according to Embodiment 1will be described. When a power supply is applied to the electric motorstator 9, the main axis 10 is rotated and driven by the electric motorrotor 8. Then, the rotational force is transmitted to the swing bearing5 through the slider 11 accommodating the decentrated slider portion 10a, and then transmitted to the swing scroll 2 d therefrom. During theoperation, the swing scroll 2 swings while the rotation being suppressedby the Oldham ring 7 that moves back and forth in the Oldham grooves 2 fof the swing scroll 2 and the Oldham grooves 3 f of the frame 3.

The frame 3 having the main bearing 4 that supports the rotation of themain axis 10 and the sub-frame 15 having, at the center, the bearingstorage portion 15 a to which the outer ring of the ball bearing 16 ispress-fitted are fixed in the sealed container 20. However, the axiscore shift of the main bearing 4 and the ball bearing 16 arises due tothe accuracy variation during the fixation or the accuracy variation ofeach component. Moreover, bending of the main axis 10 is also added, andthus the main bearing 4 and the main axis 10 and the ball bearing 16 andthe main axis 10 are not always parallel. Thus, here, in order to makethe slide surface in the main bearing 4 parallel, the sleeve 12 isaccommodated between the main axis 10 and the main bearing 4. When theaxis core shift of the main bearing 4 and the ball bearing 16 arises,the main axis 10 is inclined to the main bearing 4. However, when thesecond pivot portion 10 e contacts the inner circumferential surface ofthe sleeve 12 to absorb the inclination, the outer circumference of thesleeve 12 can always slide in parallel to the main bearing 4.

The centrifugal force generates in the swing scroll 2, and the swingscroll 2 slides in a slidable range between the slider axis 10 a of themain axis 10 and the slide surface 11 a in the slider 11. Then, the lapportion 2 a of the swing scroll 2 and the lap portion 1 a of the fixedscroll 1 contact each other to constitute the compression chamber 23.The load of the centrifugal force of the swing scroll 2 and the loadgenerating in the radial direction so as to compress the refrigerant areadded to the decentrated slider portion 10 a of the main axis 10 to bendthe decentrated slider portion 10 a. Thus, the decentrated sliderportion 10 a is not always parallel to the inside of the swing bearing 5provided at the center of the back surface opposite to the side of thepanel 2 b of the swing scroll 2 on which the lap portion 2 a is formed.Thus, here, in order to make the slide surface in the swing bearing 5parallel, the slider 11 is accommodated between the decentrated sliderportion 10 a of the main axis 10 and the swing bearing 5. When thedecentrated slider portion 10 a bends, the decentrated slider portion 10a of the main axis 10 inclines to the swing bearing 5. However, when thefirst pivot portion 10 d contacts the slider surface 11 a of the slider11 to absorb the inclination, the outer circumference of the slider 11can always slide in parallel to the swing bearing 5.

The refrigerant to be compressed by the scroll compressor is arefrigerant which is a halogenated hydrocarbon or a hydrocarbon eachhaving a carbon double bond in the composition thereof or a mixturecontaining thereof. The refrigerant is inhaled from the inhalation pipe21 to the sealed container 20 to enter the compression chamber 23 formedby the lap portion 2 a of the swing scroll 2 and the lap portion 1 a ofthe fixed scroll 1 from an inhalation port 3 a of the frame 3. Thecompression chamber 23 moves to the center of the swing scroll 2 by theswing movement of the swing scroll 2, and is compressed by furtherreducing the volume thereof. During the operation, the load by which thefixed scroll 1 and the swing scroll 2 separate from each other in theaxis direction acts by the compressed refrigerant. However, the load issupported by a bearing constituted by the thrust bearing portion 2 h onthe back surface of the panel 2 b of the swing scroll 2 d and the thrustplate 6. The compressed refrigerant passes through a discharge port 1 fof the fixed scroll 1, pushes to open a discharge valve 26, passesthrough a high-pressure portion in the sealed container 20, and isdischarged from the sealed container 20 through a discharge pipe 22.

In a series of the above-described movements, the following elementsslide to each other and constitute the sliding portion:

(a) the thrust bearing portion 2 h of the swing scroll 2 and the slidesurface 6 a of the thrust plate 6,

(b) the lap portion 2 a of the swing scroll 2 and the lap portion 1 a ofthe fixed scroll 1,

(c) the seal 24 provided at the tip face of the lap portion 1 a of thefixed scroll 1 and the bottom land 2 e at the side of the lap portion 2a of the mirror panel 2 b of the swing scroll 2,

(d) the seal 25 provided at the tip face of the lap portion 2 a of theswing scroll 2 and the bottom land 1 e at the side of the lap portion 1a of the panel 1 b of the fixed scroll 1,

(e) the Oldham grooves 2 f provided in the back face opposite to theside where the lap portion 2 a of the panel 2 b of the swing scroll 2 isformed and the upper convex portions 7 a that are the keys of the Oldhamring 7,

(f) the Oldham grooves 3 f provided near the main bearing 4 of the frame3 and the lower convex portions 7 b that are the keys of the Oldham ring7,

(g) the inner circumference of the swing bearing 5 provided at thecenter of the back surface opposite to the side where the lap portion 2a of the panel 2 b of the swing scroll 2 is formed and the outercircumference of the slider 11,

(h) the first pivot portion 10 d of the decentrated slider axis 10 a towhich the slider 11, which is decentrated with respect to the rotationcenter of the main axis 10 and drives the swing axis, is mounted and theslide surface 11 a of the slider 11,

(i) the inner circumference of the frame bearing 4 provided at thecenter of the frame 3 and the outer circumference of the sleeve 12 thatsupports the rotation of the main axis 10, and

(j) the inner circumference of the sleeve 12 and the second pivotportion 10 e of the main axis 10.

The sliding portions of the scroll compressor according to Embodiment 1are collectively shown in Table 1. In Table 1, the name of each of thetwo components (Component 1, Component 2) that constitute the slidingportions and base materials of the components are shown and performingthe surface treatment (represented by coating) or replacing by ceramicmaterials or resin described above to the components is clearly denotedby the asterisk (*).

TABLE 1 Sliding portion Examples Name Portion Base material CoatingCeramic Resin Component 1 Swing scroll Thrust bearing portion Iron base•Aluminum base * * Lap portion surface Iron base •Aluminum base * *Bottom land Iron base •Aluminum base * * Oldham groove Iron base•Aluminum base * * * Swing bearing Iron base •Aluminum base * * * Fixedscroll Lap portion surface Iron base •Aluminum base * * Bottom land Ironbase •Aluminum base * * Frame Oldham groove Iron base •Aluminumbase * * * Frame bearing Iron base •Aluminum base * * * Oldham ring Keyportion Iron base •Aluminum base * * * Key portion Iron base •Aluminumbase * * * Slider Outer circumference Iron base •Aluminum base * * Slidesurface Iron base •Aluminum base * * Sleeve Outer circumference Ironbase •Aluminum base * * Inner circumference Iron base •Aluminum base * *Thrust plate Thrust surface Iron base •Aluminum base * * Main axis Firstpivot portion Iron base •Aluminum base * * Second pivot portion Ironbase •Aluminum base * * Component 2 Thrust plate Thrust surface Ironbase •Aluminum base * * Fixed scroll Lap portion surface Iron base•Aluminum base * * Seal Sliding surface Resin (PPS, LCP, etc.) Oldhamring Key portion Iron base •Aluminum base * * * Slider Outercircumference Iron base •Aluminum base * * Swing scroll Lap portionsurface Iron base •Aluminum base * * Seal Sliding surface Resin (PPS,LCP, etc.) Oldham ring Key portion Iron base •Aluminum base * * * SleeveOuter circumference Iron base •Aluminum base * * Swing scroll Oldhamgroove Iron base •Aluminum base * * * Frame Oldham groove Iron base•Aluminum base * * * Swing scroll Swing bearing Iron base •Aluminumbase * * Main axis First pivot portion Iron base •Aluminum base * *Frame Frame bearing Iron base •Aluminum base * * Main axis Second pivotportion Iron base •Aluminum base * * Swing scroll Thrust bearing portionIron base •Aluminum base * * Slider Slide surface Iron base •Aluminumbase * * Sleeve Inner circumference Iron base •Aluminum base * *

To these sliding portions, lubricating oil of the oil sump 19 at thelower end of the sealed container 20 is supplied. More specifically, theoil pump 18 is driven by the pump axis 10 b by the rotation of the mainaxis 10, and the lubricating oil of the oil sump 19 is supplied to theabove-mentioned sliding portions through the oil hole 10 c penetratingfrom the lower end to the upper end of the main axis 10. The temperatureof these sliding portions becomes high. Thus, the atmosphere thereofbecomes the same atmosphere as that of the refrigerant having arelatively low temperature inhaled into the sealed container 20, andthus the sliding portions are cooled.

The scroll compressor according to Embodiment 1 uses, as a refrigerant,the refrigerant which is a halogenated hydrocarbon or a hydrocarbon eachhaving a carbon double bond in the composition thereof or a mixturecontaining thereof. However, the sliding surfaces of the slidingportions, whose temperature is likely to become high, are subjected tocoating, film formation, or replacement to non-metal materials, so thatthe iron or aluminum metal that can serve as a metal catalyst thatpromotes the chemical reaction of the refrigerant is not directlyexposed to the sliding surfaces of the sliding portions. Therefore, thedecomposition or polymerization of the refrigerant is suppressed, andthus the generation of sludge is suppressed to suppress troubles of thecompressor or blocking in a refrigeration circuit, which allowsobtaining reliability over a long period of time of the compressor.

In the scroll compressor of embodiments of the invention, POE(polyolester), PVE (polyvinyl ether), PAG (polalkylene glycol), PAO(poly alpha olefin), AB (alkylbenzene), MO (mineral oil), etc., whichhave been generally used heretofore, are used as the lubricating oil.The viscosity of the lubricating oils needs to be determined so thatsufficient lubrication can be achieved and the performance of the scrollcompressor does not decrease. The kinetic viscosity (at 40° C.) ispreferably adjusted to about 5 to 300 [cSt].

Embodiment 2

In Embodiment 2, a slider plate is disposed inside the slider 11 and afirst pivot portion and a slider plate are adhered to each other throughlubricating oil and constitute a sliding portion in place of using theslide surface 11 a inside the slider 11 as an adhesion surface. Theother structure is the same as that of Embodiment 1 as shown in FIG. 7.

FIG. 8 is an explanatory view of a sliding portion containing a sliderplate 27 that enters the slider 11 and the main axis 10 of a scrollcompressor of Embodiment 2 of the invention. FIG. 9 is an explanatoryview showing the sliding state of a sliding portion to which eachelement of FIG. 8 is attached. The slider 11 has the slider plate 27thereinside and the decentrated slider axis 10 a of the main axis 10 isinserted into the slider 11. To the slider plate 27, the first pivotportion 10 d provided substantially at the center of the plane portionof the decentrated slider axis 10 a of the main axis 10 is adheredthrough lubricating oil.

The slider plate 27 is formed with iron metal, such as stainless steel,alloy tool steel, or spring steel. However, the surface of the sliderplate 27 is subjected to coating of any one of DLC, DLC-Si, CrN, TiN,TiCN, WCC, VC, etc., or film formation treatment of any one of amanganese phosphate film, a molybdenum disulfide film, etc.

The first pivot portion 10 d is formed with iron metal, such as castiron or alloy steel for machine structures, which is the same materialas that of the main axis 10. However, the surface of the main axis 10including the first pivot portion 10 d provided substantially at thecenter of the plane portion of the decentrated slider axis 10 a of themain axis 10 is subjected to coating of any one of DLC, DLC-Si, CrN,TiN, TiCN, WCC, VC, etc., or film formation treatment of any one of amanganese phosphate film, a molybdenum disulfide film, etc.

The sliding portions of the scroll compressor according to Embodiment 2are shown in Table 2. In Table 2, the name of each of the two components(Component 1, Component 2) that constitute the sliding portions and basematerials of the components are shown and performing the surfacetreatment (represented as coating) or replacement to ceramic materialsor resins described above to the components is clearly shown by theasterisk (*).

TABLE 2 Sliding portion Examples Name Portion Base material CoatingCeramic Resin Component 1 Swing scroll Thrust bearing portion Iron base•Aluminum base * * Lap portion surface Iron base •Aluminum base * *Bottom land Iron base •Aluminum base * * Oldham groove Iron base•Aluminum base * * * Swing bearing Iron base •Aluminum base * * * Fixedscroll Lap portion surface Iron base •Aluminum base * * Bottom land Ironbase •Aluminum base * * Frame Oldham groove Iron base •Aluminumbase * * * Frame bearing Iron base •Aluminum base * * * Oldham ring Keyportion Iron base •Aluminum base * * * Key portion Iron base •Aluminumbase * * * Slider Outer circumference Iron base •Aluminum base * * Slidesurface Iron base •Aluminum base * * Sleeve Outer circumference Ironbase •Aluminum base * * Inner circumference Iron base •Aluminum base * *Thrust plate Thrust surface Iron base •Aluminum base * * Slider plateSurface Iron base •Aluminum base * * Surface Iron base •Aluminumbase * * Main axis First pivot portion Iron base •Aluminum base * *Second pivot portion Iron base •Aluminum base * * Component 2 Thrustplate Thrust surface Iron base •Aluminum base * * Fixed scroll Lapportion surface Iron base •Aluminum base * * Seal Sliding surface Resin(PPS, LCP, etc.) Oldham ring Key portion Iron base •Aluminum base * * *Slider Outer circumference Iron base •Aluminum base * * Swing scroll Lapportion surface Iron base •Aluminum base * * Seal Sliding surface Resin(PPS, LCP, etc.) Oldham ring Key portion Iron base •Aluminum base * * *Sleeve Outer circumference Iron base •Aluminum base * * Swing scrollOldham groove Iron base •Aluminum base * * * Frame Oldham groove Ironbase •Aluminum base * * * Swing scroll Swing bearing Iron base •Aluminumbase * * * Slider plate Surface Iron base •Aluminum base * * Frame Framebearing Iron base •Aluminum base * * * Main axis Second pivot portionIron base •Aluminum base * * Swing scroll Thrust bearing portion Ironbase •Aluminum base * * Slider Slide surface Iron base •Aluminumbase * * Main axis First pivot portion Iron base •Aluminum base * *Slider plate Surface Iron base •Aluminum base * * Sleeve Innercircumference Iron base •Aluminum base * *

The scroll compressor according to Embodiment 2 also uses, as arefrigerant, the refrigerant which is a halogenated hydrocarbon or ahydrocarbon each having a carbon double bond in the composition thereofor a mixture containing thereof. However, the sliding surfaces of thesliding portions, whose temperature is likely to become high, aresubjected to coating, film formation, or replacement to non-metalmaterials, so that the iron or aluminum metal that can serve as a metalcatalyst that promotes the chemical reaction of the refrigerant is notdirectly exposed to the sliding surfaces of the sliding portions.Therefore, the decomposition or polymerization of the refrigerant issuppressed, and thus the generation of sludge is suppressed to suppresstroubles of the compressor or blocking in a refrigeration circuit, whichallows obtaining reliability over a long period of time of thecompressor.

In addition, the following characteristic effects are demonstrated withthe structure of Embodiment 2. More specifically, the slider plate 27has a shape in which the hardness is relatively easily secured. Thus,compared with forming the slide surface 11 a on the slider 11, the costfor securing hardness required for suppressing wear can be reduced.Moreover, the wear of the slide surface 11 a can be suppressed withoutthe application of a high load to the slide surface 11 a of the slider11. Thus, a high-reliability scroll compressor can be obtained at a lowcost.

Embodiment 3

FIG. 10 is a cross sectional view showing the inside of a scrollcompressor in Embodiment 3 of the invention. FIG. 11 is an explanatoryview of a sliding portion containing the swing scroll 2 and the Oldhamring 7 and the fixed scroll 1 and the Oldham ring 7 in the compressor ofthe aspect of FIG. 10.

Embodiment 1 or Embodiment 2 describes the scroll compressor in whichthe Oldham ring 7 is disposed between the swing scroll 2 and the frame3. In contrast, Embodiment 3 describes a scroll compressor in which theOldham ring 7 is disposed between the swing scroll 2 and the fixedscroll 1 and the thrust bearing portion 2 h of the swing scroll 2 has athrust bearing member 2 g. Here, portions different from Embodiments 1and 2 will be mainly described.

The swing scroll 2 has the Oldham grooves 2 f for accommodating andsliding the lower convex portions 7 d that are keys of the Oldham ring 7at the side of the panel 2 b on which the lap portion 2 a is formed. Thefixed scroll 1 has the Oldham grooves 1 g for accommodating and slidingthe upper convex portions 7 d that are keys of the Oldham ring 7 at theside of the panel 2 b on which the lap portion 2 a is formed. Thus, theswing scroll 2 swings relative to the fixed scroll 1. In this case, theOldham grooves 2 f of the swing scroll 2 and the lower convex portions 7d of the Oldham ring 7 are slidable to each other and constitute thesliding portion. Moreover, the Oldham grooves 1 g of the fixed scroll 1and the upper convex portion 7 c of the Oldham ring 7 are slidable toeach other and constitute the sliding portion.

The Oldham grooves 2 f of the swing scroll 2 are formed with iron metal,such as cast iron, or an Al—Si alloy metal, which is the same materialas that of the swing scroll 2. However, the surface of the swing scroll2 including the Oldham grooves 2 f of the swing scroll 2 d is subjectedto coating of any one of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., orfilm formation treatment of any one of a manganese phosphate film, amolybdenum disulfide film, etc.

The Oldham grooves 1 g of the fixed scroll 1 are formed with iron metal,such as cast iron, which is the same material as that of the fixedscroll 1. However, the surface of the fixed scroll 1 including theOldham grooves 1 g of the fixed scroll 1 is subjected to coating of anyone of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., or film formationtreatment of any one of a manganese phosphate film, a molybdenumdisulfide film, etc.

The upper and lower convex portions 7 c and 7 d of the Oldham ring 7 areformed with high-rigidity and lightweight materials, such as iron metal,such as sintering, or an Al—Si alloy metal, which is the same materialas that of the Oldham ring 7. However, the surface of the Oldham ring 7including the respective convex portions 7 c and 7 d is subjected tocoating of any one of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., orfilm formation treatment of any one of a manganese phosphate film, amolybdenum disulfide film, etc.

FIG. 12 is an explanatory view of a sliding portion constituted by athrust bearing member 2 g provided at the swing scroll and the thrustplate 6 in the compressor of the aspect of FIG. 10.

The thrust bearing member 2 g provided at the swing scroll 2 and thethrust plate 6 are in a relation to be slidable to each other andconstitute the sliding portion. In Embodiment 3, the Oldham grooves 2 fare disposed at the same side where the lap portion 2 a of the panel 2 bof the swing scroll 2 is formed. Therefore, a big thrust bearing portion2 h can be formed at the back surface of the swing scroll 2 opposite tothe side where the lap portion 2 a of the panel 2 b of the swing scroll2 is formed, so that the thrust bearing member 2 g is provided. To asliding surface 6 a of the thrust plate 6, the thrust bearing member 2 gis adhered through lubricating oil. The sliding surface 6 a of thethrust plate 6 and the thrust bearing member 2 g of the swing scroll 2constitute the thrust bearing.

The swing scroll 2 is formed by iron metal such as cast iron or an Al—Sialloy metal. In contrast, for the thrust bearing member 2 g, a non-metalbearing containing PTFE, POM, carbon, etc., as the main ingredients isused. The thrust plate 6 is formed by iron metal, such as stainlesssteel, alloy tool steel, and spring steel. However, the surface of thethrust plate 6 including the sliding surfaces 6 a is subjected tocoating of any one of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., orfilm formation treatment of any one of a manganese phosphate film, amolybdenum disulfide film, etc.

The sliding portions of the scroll compressor according to Embodiment 3are shown in Table 3. In Table 3, the name of each of the two components(Component 1, Component 2) that constitute the sliding portions and basematerials of the components are shown and performing the surfacetreatment (represented as coating) or replacement to ceramic materialsor resins described above to the components is clearly shown by theasterisk (*).

TABLE 3 Sliding portion Examples Name Portion Base material CoatingCeramic Resin Component 1 Swing scroll Lap portion surface Iron base•Aluminum base * * Bottom land Iron base •Aluminum base * * Oldhamgroove Iron base •Aluminum base * * * Swing bearing Iron base •Aluminumbase * * * Thrust bearing member Iron base •Aluminum base * * * Fixedscroll Lap portion surface Iron base •Aluminum base * * Bottom land Ironbase •Aluminum base * * Oldham groove Iron base •Aluminum base * * *Frame Frame bearing Iron base •Aluminum base * * * Oldham ring Keyportion Iron base •Aluminum base * * * Key portion Iron base •Aluminumbase * * * Slider Outer circumference Iron base •Aluminum base * * Slidesurface Iron base •Aluminum base * * Sleeve Outer circumference Ironbase •Aluminum base * * Inner circumference Iron base •Aluminum base * *Thrust plate Thrust surface Iron base •Aluminum base * * Slider plateSurface Iron base •Aluminum base * * Surface Iron base •Aluminumbase * * Main axis First pivot portion Iron base •Aluminum base * *Second pivot portion Iron base •Aluminum base * * Component 2 Fixedscroll Lap portion surface Iron base •Aluminum base * * Seal Slidingsurface Resin (PPS, LCP, etc.) Oldham ring Key portion Iron base•Aluminum base * * Slider Outer circumference Iron base •Aluminumbase * * Thrust plate Thrust surface Iron base •Aluminum base * * *Swing scroll Lap portion surface Iron base •Aluminum base * * SealSliding surface Resin (PPS, LCP, etc.) Oldham ring Key portion Iron base•Aluminum base * * * Sleeve Outer circumference Iron base •Aluminumbase * * Swing scroll Oldham groove Iron base •Aluminum base * * * Fixedscroll Oldham groove Iron base •Aluminum base * * * Swing scroll Swingbearing Iron base •Aluminum base * * * Slider plate Surface Iron base•Aluminum base * * Frame Frame bearing Iron base •Aluminum base * * *Main axis Second pivot portion Iron base •Aluminum base * * Swing scrollThrust bearing member Iron base •Aluminum base * * * Slider Slidesurface Iron base •Aluminum base * * Main axis First pivot portion Ironbase •Aluminum base * * Slider plate Surface Iron base •Aluminumbase * * Sleeve Inner circumference Iron base •Aluminum base * *

The scroll compressor according to Embodiment 3 also uses, as arefrigerant, the refrigerant which is a halogenated hydrocarbon or ahydrocarbon each having a carbon double bond in the composition thereofor a mixture containing thereof. However, the sliding surfaces of thesliding portions, whose temperature is likely to become high, aresubjected to coating, film formation, or replacement to non-metalmaterials, so that the iron or aluminum metal that can serve as a metalcatalyst that promotes the chemical reaction of the refrigerant is notdirectly exposed to the sliding surfaces of the sliding portions.Therefore, the decomposition or polymerization of the refrigerant issuppressed, and thus the generation of sludge is suppressed to suppresstroubles of the compressor or blocking in a refrigeration circuit, whichallows obtaining reliability over a long period of time of thecompressor.

In addition, by structuring as in Embodiment 3, when the swing scroll 2swings, the phase of the fixed scroll 1 and the swing scroll 2 can bedirectly determined by the Oldham ring 7 without through the frame 3.Therefore, the phase when the fixed scroll 1 and the swing scroll 2swing can be held with higher accuracy and the leak from the compressionchamber 23 formed by the lap portion 2 a of the swing scroll 2 and thelap portion 1 a of the fixed scroll 1 is reduced, thereby obtaining ascroll compressor having higher performance. Moreover, since the thrustbearing portion 2 h of the swing scroll 2 is enlarged and the thrustbearing member 2 g is disposed thereto, the sliding properties of thethrust bearing increase, and thus the performance can be improved or thereliability can be increased due to a reduction in the sliding loss.

Embodiment 4

FIG. 13 is a structure diagram showing the structure of a scrollcompressor according to Embodiment 4 of the invention. FIG. 14 is anexplanatory view of the sliding portion containing the thrust plate 6provided at the swing scroll 2 and a thrust bearing member 3 g providedat the frame 3 in the compressor of the aspect of FIG. 13.

The scroll compressor of Embodiment 4 is provided with the thrust plate6 at the back surface of the swing scroll 2 opposite to the side of thepanel 2 b of the swing scroll 2 on which the lap portion 2 a is formedand is provided with the thrust bearing member 3 g at a thrust supportportion of the frame 3. Here, portions different from Embodiments 1, 2,and 3 will be mainly described. In the sealed container 20, acompression mechanism portion containing the fixed scroll 1, the swingscroll 2, the frame 3, etc., and an electric motor containing theelectric motor stator 9 and the electric motor rotor 8 are fixed througha holder 28. At the back surface opposite to the side of the panel 2 bof the swing scroll 2 on which the lap portion 2 a is formed, the thrustplate 6 is provided and the thrust plate 6 and the thrust bearing member3 g provided at the thrust support portion of the frame 3 constitute thethrust bearing. Therefore, the thrust plate 6 and the thrust bearingmember 3 g are slidable to each other and constitute the slidingportion.

At the back surface opposite to the side of the panel 2 b of the swingscroll 2 on which the lap portion 2 a is formed, the Oldham grooves 2 ffor accommodating the upper convex portions that are keys of the Oldhamring 7 are provided. Therefore, the thrust plate 6 that is shaped insuch a manner as to avoid the Oldham grooves 2 f is stuck with anadhesive or a bolt. The thrust bearing member 3 g is provided at thethrust support portion near the main bearing 4 of the frame 3.

The thrust plate 6 is formed with iron metal, such as stainless steel,alloy tool steel, or spring steel. However, the surface of the thrustplate 6 is subjected to coating of any one of DLC, DLC-Si, CrN, TiN,TiCN, WCC, VC, etc., or film formation treatment of any one of amanganese phosphate film, a molybdenum disulfide film, etc. The frame 3is formed with iron metal, such as cast iron and, for the thrust bearingmember 3 g, a non-metal bearing containing PTFE, POM, carbon, etc., asthe main ingredients is used.

The sliding portions of the scroll compressor according to Embodiment 4are shown in Table 4. In Table 4, the name of each of the two components(Component 1, Component 2) that constitute the sliding portions and basematerials of the components are shown and performing the surfacetreatment (represented as coating) or replacement to ceramic materialsor resins described above to the components is clearly shown by theasterisk (*).

TABLE 4 Sliding portion Examples Name Portion Base material CoatingCeramic Resin Component 1 Swing scroll Lap portion surface Iron base•Aluminum base * * Bottom land Iron base •Aluminum base * * Oldhamgroove Iron base •Aluminum base * * * Swing bearing Iron base •Aluminumbase * * * Fixed scroll Lap portion surface Iron base •Aluminum base * *Bottom land Iron base •Aluminum base * * Frame Frame bearing Iron base•Aluminum base * * * Oldham groove Iron base •Aluminum base * * * Thrustbearing member Iron base •Aluminum base * * * Oldham ring Key portionIron base •Aluminum base * * Key portion Iron base •Aluminum base * *Slider Outer circumference Iron base •Aluminum base * * Slide surfaceIron base •Aluminum base * * Sleeve Outer circumference Iron base•Aluminum base * * Inner circumference Iron base •Aluminum base * *Thrust plate Thrust surface Iron base •Aluminum base * * Slider plateSurface Iron base •Aluminum base * * Surface Iron base •Aluminumbase * * Main axis First pivot portion Iron base •Aluminum base * *Second pivot portion Iron base •Aluminum base * * Component 2 Fixedscroll Lap portion surface Iron base •Aluminum base * * Seal Slidingsurface Resin (PPS, LCP, etc.) Oldham ring Key portion Iron base•Aluminum base * * Slider Outer circumference Iron base •Aluminumbase * * Swing scroll Lap portion surface Iron base •Aluminum base * *Seal Sliding surface Resin (PPS, LCP, etc.) Sleeve Outer circumferenceIron base •Aluminum base * * Oldham ring Key portion Iron base •Aluminumbase * * Thrust plate Thrust surface Iron base •Aluminum base * * Swingscroll Oldham groove Iron base •Aluminum base * * * Frame Oldham grooveIron base •Aluminum base * * * Swing scroll Swing bearing Iron base•Aluminum base * * * Slider plate Surface Iron base •Aluminum base * *Frame Frame bearing Iron base •Aluminum base * * * Main axis Secondpivot portion Iron base •Aluminum base * * Frame Thrust bearing memberIron base •Aluminum base * * * Slider Slide surface Iron base •Aluminumbase * * Main axis First pivot portion Iron base •Aluminum base * *Slider plate Surface Iron base •Aluminum base * * Sleeve Innercircumference Iron base •Aluminum base * *

The scroll compressor according to Embodiment 4 also uses, as arefrigerant, the refrigerant which is a halogenated hydrocarbon or ahydrocarbon each having a carbon double bond in the composition thereofor a mixture containing thereof. However, the sliding surfaces of thesliding portions, whose temperature is likely to become high, aresubjected to coating, film formation, or replacement to non-metalmaterials, so that the iron or aluminum metal that can serve as a metalcatalyst that promotes the chemical reaction of the refrigerant is notdirectly exposed to the sliding surfaces of the sliding portions.Therefore, the decomposition or polymerization of the refrigerant issuppressed, and thus the generation of sludge is suppressed to suppresstroubles of the compressor or blocking in a refrigeration circuit, whichallows obtaining reliability over a long period of time of thecompressor.

In addition, by structuring as in Embodiment 4, the size of the thrustbearing member 3 g can be reduced and the performance can be improveddue to a reduction in the sliding loss or the amount of the bearingmember, which is expensive, can be reduced while maintaining the slidingproperties of the thrust bearing. Therefore, a high-reliability andhigh-performance scroll compressor can be obtained at a low cost.

Embodiment 5

FIG. 15 is a structure diagram showing the structure of a scrollcompressor according to Embodiment 5 of the invention. FIG. 16 is anenlarged explanatory view of a compression mechanism portion in thecompressor of the aspect of FIG. 15.

The scroll compressor of Embodiment 5 has an aspect in which the frame 3of Embodiments 1 to 4 is divided into a first frame (also referred to asa frame A) 29 and a second frame (also referred to as a frame B) 30 andthe sub-frame 15 of the axis lower portion is abolished. In the sealedcontainer 20, a compression mechanism portion provided with the fixedscroll 1, the swing scroll 2, and the first frame 29 and an electricmotor constituted by the electric motor stator 9 and the electric motorrotor 8 are fixed through the second frame 30. The swing bearing 5 isprovided at the tip of the main axis 10 while being decentrated and aswing axis pivot portion 2 k is provided at the center of the back faceopposite to the lap portion 2 a of the mirror panel 2 b of the swingscroll 2. Here, portions different from Embodiments 1 to 4 will bemainly described.

The inside of the frame bearing 4 c provided at the center of the firstframe 29 and the outer circumference of a first outer circumferentialportion 10 g positioned at the upper end of the main axis 10 are adheredto each other through lubricating oil to constitute a main bearingportion A. They are slidable to each other and constitute the slidingportion. Moreover, the inside of the frame bearing 4 provided at thecenter of the second frame 30 and the outer circumference of a secondouter circumferential portion 10 h positioned substantially at thecenter of the main axis 10 are adhered to each other through lubricatingoil to constitute a main bearing portion B. They are also slidable toeach other and constitute the sliding portion. The self weight of themain axis 10 is supported by an axial thrust surface 10 f of the mainaxis 10 and a secondary thrust bearing 30 g of the second frame 30. Theswing bearing 5 is embedded in the upper end portion of the main axis 10at a position decentrated relative to the rotation center of the mainaxis 10. The swing bearing 5 accommodates the sleeve 12 and, into thesleeve 12, the swing axis pivot portion 2 k provided at the center ofthe back surface opposite to the lap portion 2 a of the panel 2 b of theswing scroll 2 is inserted. To the inner circumferential surface insidethe sleeve 12, the swing axis pivot portion 2 k is adhered throughlubricating oil. The swing axis pivot portion 2 k is a portion projectedfrom the cylindrical surface in an approximately circular shape orspherical shape.

The thrust plate 6 pasted, by adhesion, with a bolt, or the like, to theback surface of the side opposite to the side of the panel 2 b of theswing scroll 2 on which the lap portion 2 a is formed and a thrustbearing member (also referred to as a thrust metal) 29 g provided at thethrust support portion near the frame bearing 4 c of the first frame 29constitute the thrust bearing. Therefore, the thrust plate 6 and thethrust bearing member 2 g are slidable to each other and constitute thesliding portion.

Here, for the inner diameter of the frame bearing 4 c and a framebearing 4 d and the surface of the secondary thrust bearing 30 g, anon-metal bearing containing PTFE, POM, carbon, etc., as the mainingredients is used. The first outer circumferential portion 10 g of themain axis 10, the second outer circumferential portion 10 h, and theaxial thrust surface 10 f are formed with iron metal, such as iron,which is the same material as that of the main axis 10. However, thesurface of the main axis 10 including the same is subjected to coatingof any one of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., or filmformation treatment of any one of a manganese phosphate film, amolybdenum disulfide film, etc.

The outer circumference and the inner circumferential surface 12 a ofthe sleeve 12 are formed with a high-hardness iron metal, such assintering or alloy tool steel, which is the same material as that of thesleeve 12. However, the surface of the sleeve 12 including the outercircumference and the inner circumferential surface 12 a of the sleeve12 d is subjected to coating of any one of DLC, DLC-Si, CrN, TiN, TiCN,WCC, VC, etc., or film formation treatment of any one of a manganesephosphate film, a molybdenum disulfide film, etc.

The swing axis pivot portion 2 k is formed with iron metal, such as castiron, or an Al—Si alloy metal, which is the same material as that of theswing scroll 2. However, the surface of the swing scroll 2 including theswing axis pivot portion 2 k is subjected to coating of any one of DLC,DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., or film formation treatment ofany one of a manganese phosphate film, a molybdenum disulfide film, etc.

The sliding portions of the scroll compressor according to Embodiment 5are shown in Table 5. In Table 5, the name of each of the two components(Component 1, Component 2) that constitute the sliding portions and basematerials of the components are shown and performing the surfacetreatment (represented as coating) or replacement to ceramic materialsor resins described above to the components is clearly shown by theasterisk (*).

TABLE 5 Sliding portion Examples Name Portion Base material CoatingCeramic Resin Component 1 Swing scroll Bottom land Iron base •Aluminumbase * * Oldham groove Iron base •Aluminum base * * * Swing axis pivotportion Iron base •Aluminum base * * Fixed scroll Bottom land Iron base•Aluminum base * * Frame A Frame bearing Iron base •Aluminum base * * *Oldham groove Iron base •Aluminum base * * * Frame B Frame bearing Ironbase •Aluminum base * * * Secondary thrust bearing Iron base •Aluminumbase * * * Oldham ring Key portion Iron base •Aluminum base * * * Keyportion Iron base •Aluminum base * * * Sleeve Outer circumference Ironbase •Aluminum base * * Inner circumference Iron base •Aluminum base * *Thrust plate Thrust surface Iron base •Aluminum base * * Main axis Swingbearing Iron base •Aluminum base * * * Outer circumference 1 Iron base•Aluminum base * * Outer circumference 2 Iron base •Aluminum base * *Axial thrust surface Iron base •Aluminum base * * Thrust metal Thrustsurface Iron base •Aluminum base * * * Component 2 Seal Sliding surfaceResin (PPS, LCP, etc.) Oldham ring Key portion Iron base •Aluminumbase * * * Sleeve Inner circumference Iron base •Aluminum base * * SealSliding surface Resin (PPS, LCP, etc.) Main axis Outer circumference 1Iron base •Aluminum base * * Oldham ring Key portion Iron base •Aluminumbase * * * Main axis Outer circumference 2 Iron base •Aluminum base * *Main axis Axial thrust surface Iron base •Aluminum base * * Swing scrollOldham groove Iron base •Aluminum base * * * Frame 1 Oldham groove Ironbase •Aluminum base * * * Main axis Swing bearing Iron base •Aluminumbase * * * Swing scroll Swing axis pivot portion Iron base •Aluminumbase * * Thrust metal Thrust surface Iron base •Aluminum base * * *Sleeve Outer circumference Iron base •Aluminum base * * Frame A Framebearing Iron base •Aluminum base * * * Frame B Frame bearing Iron base•Aluminum base * * * Frame B Secondary thrust bearing Iron base•Aluminum base * * * Thrust plate Thrust surface Iron base •Aluminumbase * *

The scroll compressor according to Embodiment 5 also uses, as arefrigerant, the refrigerant which is a halogenated hydrocarbon or ahydrocarbon each having a carbon double bond in the composition thereofor a mixture containing thereof. However, the sliding surfaces of thesliding portions, whose temperature is likely to become high, aresubjected to coating, film formation, or replacement to non-metalmaterials, so that the iron or aluminum metal that can serve as a metalcatalyst that promotes the chemical reaction of the refrigerant is notdirectly exposed to the sliding surfaces of the sliding portions.Therefore, the decomposition or polymerization of the refrigerant issuppressed, and thus the generation of sludge is suppressed to suppresstroubles of the compressor or blocking in a refrigeration circuit, whichallows obtaining reliability over a long period of time of thecompressor.

In addition, according to the structure of Embodiment 5, the swingbearing 5 that receives the centrifugal force or the load of the swingscroll 2 and the frame bearing 4 c that supports the rotation of themain axis 10 are at the same position, and thus bending of the main axis10 can be reduced. Therefore, pivot portion processing to the main axis10, which is complicated processing, becomes unnecessary, andhigh-reliability and a high-performance scroll compressor can beobtained at a low cost.

Embodiment 6

FIG. 17 is a cross sectional view showing the inside of the scrollcompressor according to Embodiment 6 of the invention. Also here,portions different from Embodiments 1 to 4 will be mainly described. Theouter circumferential portion of the fixed scroll 1 is fastened to aguide frame 32 with a bolt. Oldham grooves 1 f are formed at the side ofthe panel 1 b of the fixed scroll 1 on which the lap portion 1 a isformed and slidably accommodate the upper convex portions 7 c that arekeys of the Oldham ring 7. Furthermore, the inhalation pipe 21 ispress-fitted penetrating the sealed container 20 from the side surfaceof the fixed scroll 1. The Oldham grooves 2 f are formed at the side ofthe panel 2 b on which the lap portion 2 a is formed on the swing scroll2 facing the fixed scroll 1 and slidably accommodate the lower convexportions (not shown) that are keys of the Oldham ring 7. The swingbearing 5 is provided substantially at the center of the back surfaceopposite to the lap portion 2 a of the panel 2 b of the swing scroll 2.At the outer circumference of the back surface opposite to the lapportion 2 a, a thrust bearing 2 h is slidable to a thrust bearingportion 31 a of a compliant frame 31. At the panel 2 b of the swingscroll 2, an air bleed opening 2 j that communicates the lap portion 2 aside and the thrust bearing 2 h side is formed. Thus, by the revolutionof the swing scroll 2 d, the air bleed opening 2 j and an openingportion 31 b of the compliant frame 31 open.

At the center of the compliant frame 31, a main bearing 31 c thatradially supports the main axis 10 rotated and driven by the electricmotor and an auxiliary main bearing 31 d are formed. Moreover, thecompliant frame 31 is provided with an opening portion 31 b that opensto a frame space 31 e from the surface of the thrust bearing portion 31a. A refrigerant whose pressure is adjusted to an appropriate pressureby a pressure adjustment valve (not shown) passes through the air bleedopening 2 j from the lap portion 2 a side of the panel 2 b of the swingscroll 2, and is taken into the frame space 31 e through the openingportion 31 b.

The outer circumference of the guide frame 32 is fixed to the sealedcontainer 20 by shrink fitting or welding. At the upper inside of theguide frame 32, an upper sliding cylindrical surface 32 a is formed andis engaged with an upper sliding cylindrical surface 31 f formed at theupper portion of the outer circumferential surface of the compliantframe 31. At the lower inside of the guide frame 32, a lower slidingcylindrical surface 32 b is formed and is engaged with a lower slidingcylindrical surface 31 g formed at the lower portion of the outercircumferential surface of the compliant frame 31. A space defined bythe inner circumferential surface of the guide frame 32, the uppersliding cylindrical surface 32 a, the lower sliding cylindrical surface32 b, the compliant frame 31, the upper sliding cylindrical surface 31f, and the lower sliding cylindrical surface 31 g is the frame space 31e.

At the upper end of the side of the swing scroll 2 of the main axis 10,a main axis decentrated portion 10 h that is rotatably engaged with theswing bearing 5 is formed at the back surface opposite to the side ofthe panel 2 b of the swing scroll 2 on which the lap portion 2 a isformed. Moreover, a first balancer 13 b is attached to the lower sidethereof. At a further lower portion, a main axis portion 10 k that isrotatably engaged with the main bearing 31 c and the auxiliary mainbearing 31 d of the compliant frame 31 is formed.

At the lower end of the main axis 10, a secondary axis portion 10 j thatis rotatably engaged with a secondary bearing 15 b of the sub-frame 15is formed. Between the secondary axis portion 10 j and the main axisportion 10 k, the electric motor rotor 8 is attached. To the upper endside of the electric motor rotor 8, a second balancer 13 a is fastenedand to the lower end side thereof, a third balancer 14 is fastened.Thus, the static balance and the dynamic balance are maintained by threebalancers including the first balancer 13 b. To the lower end of themain axis 10, an oil pipe 18 is attached and pumps up lubricating oil ofthe oil sump 19 of the bottom of the sealed container 20 to supply thelubricating oil to each sliding portion through the oil hole 10 a of themain axis 10. At the lowermost end of the main axis 10, the sub-frame 15is provided with an axial thrust receiver 15 c for supporting the selfweight of the main axis 10.

Next, the operation of the scroll compressor will be described. Sincethe pressure inside the sealed container 20 becomes as high as that of adischarge gas atmosphere at a steady state, the lubricating oil of theoil sump 19 in the sealed container 20 is guided to a swing bearingspace 37 a through the oil pipe 18 and the oil hole 10 c of the mainaxis 10. Then, the high-pressure lubricating oil is reduced by the swingbearing 5 to have an intermediate pressure that is higher than theinhalation pressure and is equal to or lower than the dischargepressure, and then flows into a boss outside space 37 b. In contrast,the air bleed opening 2 j provided at the mirror panel 2 b of the swingscroll 2 always or intermittently opens to the vicinity of the thrustbearing of an opening portion 31 b provided at the compliant frame 31.Therefore, the refrigerant having an intermediate pressure that ishigher than the inhalation pressure and lower than the dischargepressure during compression from the compression chamber 23 formed bythe fixed scroll 1 and the swing scroll 2 is guided to the frame space31 e through the air bleed opening 2 j of the swing scroll 2 and theopening portion 31 b of the compliant frame 31. To the compliant frame31, the total force of the force resulting from the intermediatepressure of the boss outside space 37 b and the pressing force from theswing scroll 2 through the thrust bearing 31 a acts as a downward force.In contrast, the total force of the force resulting from theintermediate pressure of the frame space 31 e and the force resultingfrom the high pressure that acts on a portion of the lower end surfaceexposed to the high-pressure atmosphere acts as an upward force. It isset that the upward force is larger than the downward force at a steadystate. Therefore, with respect to the compliant frame 31, the uppersliding cylindrical surface 31 f is guided to the upper slidingcylindrical surface 32 a of the guide frame 32 and the lower slidingcylindrical surface 31 g is guided to the lower sliding cylindricalsurface 32 b of the guide frame 32 d. More specifically, the compliantframe 31 is slidable to the guide frame 32 and floats up at the side ofthe fixed scroll 1. The swing scroll 2 pressed against the compliantframe 31 through the thrust bearing 31 a floats up at the upper portion.As a result, the tooth crest and the bottom land 2 e of the swing scroll2 contact the tooth crest and the bottom land 1 e of the fixed scroll 1,respectively, and slide.

The thrust bearing 31 a provided at the center of the compliant frame 31and the thrust bearing 2 h at the back surface opposite to the lapportion 2 a of the panel 2 b of the swing scroll 2 are slidable to eachother and constitute the sliding portion. In the upper slidingcylindrical surface and the lower sliding cylindrical surface 31 g ofthe compliant frame 31 and the upper sliding cylindrical surface 32 aand the lower sliding cylindrical surface 32 b of the guide frame 32,the upper portions and the lower portions are slidable to each other,respectively, and constitute the sliding portion.

The thrust bearing 31 a, the upper sliding cylindrical surface 31 f, andthe lower sliding cylindrical surface 31 g of the compliant frame 31 areformed with iron metal, such as cast iron, which is the same material asthat of the compliant frame 31. However, the surface of the compliantframe 31 including the thrust bearing 31 a, the upper slidingcylindrical surface 31 f, and the lower sliding cylindrical surface 31 gis subjected to coating of any one of DLC, DLC-Si, CrN, TiN, TiCN, WCC,VC, etc., or film formation treatment of any one of a manganesephosphate film, a molybdenum disulfide film, etc.

The upper sliding cylindrical surface 32 a and the lower slidingcylindrical surface 32 b of the guide frame 32 are formed with ironmetal, such as cast iron, which is the same material as that of theguide frame 32. However, the surface of the guide frame 32 including theupper sliding cylindrical surface 32 a and the lower sliding cylindricalsurface 32 b of the guide frame 32 is subjected to coating of any one ofDLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., or film formation treatmentof any one of a manganese phosphate film, a molybdenum disulfide film,etc.

The thrust bearing 2 h at the back surface opposite to the lap portion 2a of the panel 2 b of the swing scroll 2 is formed with iron metal, suchas cast iron, or an Al—Si alloy metal, which is the same material asthat of the swing scroll 2. However, the surface of the swing scroll 2including the thrust bearing portion 2 h is subjected to coating of anyone of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., or film formationtreatment of any one of a manganese phosphate film, a molybdenumdisulfide film, etc.

The tooth crest of the swing scroll 2 and the bottom land of the fixedscroll 1 and the bottom land of the swing scroll 2 and the tooth crestof the fixed scroll 1 constitute sliding portions. The tooth crest andthe bottom land of the swing scroll 2 are formed with iron metal, suchas cast iron, or an Al—Si alloy metal, which is the same material asthat of the swing scroll 2. However, the surface of the swing scroll 2including the tooth crest and bottom land of the swing scroll 2 d issubjected to coating of any one of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC,etc., or film formation treatment of any one of a manganese phosphatefilm, a molybdenum disulfide film, etc.

The tooth crest and the bottom land of the fixed scroll 1 are formedwith iron metal, such as cast iron or an Al—Si alloy metal, which is thesame material as that of the fixed scroll 1. However, the surface of thefixed scroll 1 including the tooth crest and the bottom land of thefixed scroll 1 is subjected to coating of any one of DLC, DLC-Si, CrN,TiN, TiCN, WCC, VC, etc., or film formation treatment of any one of amanganese phosphate film, a molybdenum disulfide film, etc.

The main bearing 31 c and the auxiliary main bearing 31 d provided atthe middle portion of the compliant frame 31 and the main axis 10 andthe secondary axis portion 10 j at the lower end of the main axis 10 andthe secondary bearing 15 b of the sub-frame 15, and the lowest end ofthe main axis 10 and the axial thrust receiver 15 c provided at thesub-frame 15 are slidable to each other, respectively, and constitutesliding portions. In these sliding portions, for the main bearing 31 cand the auxiliary main bearing 31 d of the compliant frame 31, anon-metal bearing containing PTFE, POM, carbon, etc., as the mainingredients is used.

The main axis portion 10 k and the secondary axis portion 10 j of themain axis 10 and the lowest end of the main axis 10 are formed with ironmetal, such as iron, which is the same material as that of the main axis10. However, the surface of the main axis 10 including the main axisportion 10 k and the secondary axis portion 10 j of the main axis 10 andthe lowest end of the main axis 10 is subjected to coating of any one ofDLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., or film formation treatmentof any one of a manganese phosphate film, a molybdenum disulfide film,etc.

For the secondary bearing 15 b of the sub-frame 15, a non-metal bearingcontaining PTFE, POM, carbon, etc., as the main ingredients is used. Theaxial thrust receiver 15 c of the sub-frame 15 is formed with ironmetal, such as iron, which is the same material as that of the sub-frame15. However, the surface of the sub-frame 15 including the axial thrustreceiver 15 c of the sub-frame 15 is subjected to coating of any one ofDLC-Si, CrN, TiN, TiCN, WCC, VC, etc., or film formation treatment ofany one of a manganese phosphate film, a molybdenum disulfide film, etc.

The sliding portions of the scroll compressor according to Embodiment 6are shown in Table 6. In Table 6, the name of each of the two components(Component 1, Component 2) that constitute the sliding portions and basematerials of the components are shown and performing the surfacetreatment (represented as coating) or replacement to ceramic materialsor resins described above to the components is clearly shown by theasterisk (*).

Sliding portion Examples Name Portion Base material Coating CeramicResin Component 1 Swing scroll Tooth crest Iron base •Aluminum base * *Bottom land Iron base •Aluminum base * * Oldham groove Iron base•Aluminum base * * * Thrust surface Iron base •Aluminum base * * * Swingbearing Iron base •Aluminum base * * * Fixed scroll Tooth crest Ironbase •Aluminum base * * Bottom land Iron base •Aluminum base * * Oldhamgroove Iron base •Aluminum base * * * Compliant frame Thrust surfaceIron base •Aluminum base * * Sliding cylindrical surface Iron base•Aluminum base * * Main bearing Iron base •Aluminum base * * * Auxiliarymain bearing Iron base •Aluminum base * * * Guide frame Sliding surfaceIron base •Aluminum base * * * Oldham ring Key portion Iron base•Aluminum base * * * Key portion Iron base •Aluminum base * * * Mainaxis Swing axis Iron base •Aluminum base * * Main axis portion Iron base•Aluminum base * * Main axis portion Iron base •Aluminum base * * Lowestend Iron base •Aluminum base * * Secondary axis portion Iron base•Aluminum base * * Sub-frame Secondary axis portion Iron base •Aluminumbase * * * Axial thrust surface Iron base •Aluminum base * * Component 2Fixed scroll Bottom land Iron base •Aluminum base * * Fixed scroll Toothcrest Iron base •Aluminum base * * Oldham ring Key portion Iron base•Aluminum base * * * Compliant frame Thrust surface Iron base •Aluminumbase * * Main axis Swing axis Iron base •Aluminum base * * Swing scrollBottom land Iron base •Aluminum base * * Swing scroll Tooth crest Ironbase •Aluminum base * * Oldham ring Key portion Iron base •Aluminumbase * * * Swing scroll Thrust surface Iron base •Aluminum base * * *Guide frame Sliding surface Iron base •Aluminum base * * * Main axisOuter circumference 1 Iron base •Aluminum base * * Main axis Outercircumference 2 Iron base •Aluminum base * * Compliant frame Slidingcylindrical surface Iron base •Aluminum base * * Swing scroll Oldhamgroove Iron base •Aluminum base * * * Fixed scroll Oldham groove Ironbase •Aluminum base * * * Swing scroll Swing bearing Iron base •Aluminumbase * * * Compliant frame Main bearing Iron base •Aluminum base * * *Compliant frame Auxiliary main bearing Iron base •Aluminum base * * *Sub-frame Axial thrust surface Iron base •Aluminum base * * Sub-frameSecondary bearing Iron base •Aluminum base * * * Main axis Secondaryaxis portion Iron base •Aluminum base * * Main axis Lowest end Iron base•Aluminum base * *

The scroll compressor according to Embodiment 6 also uses, as arefrigerant, the refrigerant which is a halogenated hydrocarbon or ahydrocarbon each having a carbon double bond in the composition thereofor a mixture containing thereof. However, the sliding surfaces of thesliding portions, whose temperature is likely to become high, aresubjected to coating, film formation, or replacement to non-metalmaterials, so that the iron or aluminum metal that can serve as a metalcatalyst that promotes the chemical reaction of the refrigerant is notdirectly exposed to the sliding surfaces of the sliding portions.Therefore, the decomposition or polymerization of the refrigerant issuppressed, and thus the generation of sludge is suppressed to suppresstroubles of the compressor or blocking in a refrigeration circuit, whichallows obtaining reliability over a long period of time of thecompressor.

In addition, according to the structure of Embodiment 6, the leak fromthe top end of the lap portion can be reduced, without using sealmaterials, by bringing the tooth crest and the bottom land of the swingscroll 2 into contact with the bottom land and the tooth crest of thefixed scroll 1, respectively. Since a pivot portion is not provided,pivot portion processing becomes unnecessary. Thus, a high-reliabilityand high-performance scroll compressor can be obtained at a lower cost.

Embodiment 7

FIG. 18 is a cross sectional view showing the inside of the scrollcompressor according to Embodiment 7 of the invention. Here, portionsdifferent from Embodiments 1 and 6 will be mainly described.

The compressor has the sealed container 20, in which an electric motorcontaining the electric motor stator 9 and the electric motor rotor 8 isaccommodated in the container upper portion and a machine component thatconstitutes the compression mechanism portion for compressing arefrigerant is accommodated in the container lower portion. Above theelectric motor at the upper portion of the side wall of the sealedcontainer 20, the inhalation pipe 21 for inhaling a refrigerant gasprotrudes to the side. From a position corresponding to the machinecomponent of the lower portion of the side wall of the sealed container20, the discharge pipe 22 for discharging a compressed refrigerant tothe outside protrudes. In the electric motor, the upper portion of themain axis 10 is inserted to the electric motor rotor 8, the centralportion of the main axis 10 penetrates the machine component to extendto the lower portion of the sealed container 20, and the oil pump 18 isprovided at the lowest end of the main axis 10 and is immersed inlubricating oil enclosed in the oil sump 19 at the lower portion of thesealed container. The oil pump 18 is driven by the rotation of the mainaxis 10 driven by the electric motor rotor 8. In order to supply thelubricating oil pumped up by the oil pump 18 to each sliding portion ofthe machine component, the oil hole 10 c is formed at the main axiswhile penetrating the main axis 10.

The machine component constituting the compression mechanism portion hasa pair of upper and lower fixed scrolls 33 and 34. The respective fixedscrolls 33 and 34 are fixed onto the inner wall face of the sealedcontainer 20 through the holder 28. Above the upper fixed scroll 33, theelectric motor stator 9 is fixed through the holder 28. At the center ofthe mirror panel 33 b of the upper fixed scroll 33, an upper mainbearing 4 a for passing the main axis 10 is provided. At the lower faceof a mirror panel 33 b, a spiral-shaped lap portion 33 a is provided.The lower fixed scroll 34 is substantially symmetrical to the upperfixed scroll 33. At the center of a mirror panel 34 b of the lower fixedscroll 34, a lower main bearing 4 b for passing the main axis 10 andaccommodating the sleeve 12 is provided. At the upper surface of themirror panel 34 b, a spiral-shaped lap portion 34 a is provided. Then,the pair of upper and lower fixed scrolls 33 and 34 are disposed so thatthe spiral sides face each other. A swing scroll 35 is disposed betweenthese fixed scrolls 33 and 34. The swing scroll 35 has spiral-shaped lapportions 35 a and 35 c at both the upper and lower sides of a disk-likemirror panel 35 b. At the center of the mirror panel 35 b, the swingbearing 5 for passing the decentrated slider portion 10 a providedsubstantially at the center of the main axis 10 and accommodating theslider 11.

At the upper surface side of the panel 35 b of the swing scroll 35, thesurface of the lap portion 35 a at the upper surface side of the swingscroll 35 contacts the surface of the lap portion 33 a of the upperfixed scroll 33 at two or more portions, and compression chambers 23 forcompressing a refrigerant gas are formed between the contact portions.At the lower surface side of the panel 35 b of the swing scroll 35, thecompression chambers 23 for compressing a refrigerant gas are formedbetween the lap portion 35 c at the lower surface side of the swingscroll 35 and the lap portion 34 a at the lower fixed scroll 34,similarly as in the upper surface side.

At the upper surface side of the panel 35 b of the swing scroll 35, theseal 25 is provided at the tooth crest of the lap portion 35 a at theupper surface side of the swing scroll 35 and the seal 24 is provided atthe tooth crest of the lap portion 33 a of the upper fixed scroll 33,respectively. Then, the swing scroll 35 is lightly pressed against theside of the lower fixed scroll 34 side with the back pressure of theseals 25 and 24. Thus, the tooth crest of the lap portion 35C at thelower side of the swing scroll 35 and the bottom land 34 e of the lowerfixed scroll 34 are brought into moderate contact with each other andthe bottom land 35 e at the lower side of the swing scroll 35 and thetooth crest of the lap portion 34 a of the fixed scroll 34 are broughtinto moderate contact with each other. Thus, the leak of the refrigerantfrom the tooth crest of the lap portion is suppressed.

At the central portion of the swing scroll 35, the swing bearing 5 towhich the decentrated slider portion 10 a of the main axis 10 isinserted and which accommodates the slider 11 is formed. Boss portionshaving the almost same height as the height of the lap portions 35 a and35 c are formed at both ends of the swing bearing 5 and a seal ring 36for dividing the compression chamber 23 and a space for accommodatingthe slider 11 is provided and slides with seal ring sliding surfaces 33k and 34 k of the upper and lower fixed scrolls 33 and 34. Thedecentrated slider portion 10 a of the main axis 10 is decentratedrelative to the rotation center of the main axis 10 by the length inwhich the surfaces of the upper and lower lap portions 35 a and 35 c ofthe swing scroll 35 contact the surfaces of the lap portions 33 a and 34a of the fixed scroll 33 and 34, respectively.

At the side of the outer circumference of the upper and lower fixedscrolls 33 and 34, an inhalation port through which a refrigerant flowsinto the compression chambers 23 from the inside of the sealed container20 is provided. In the compression chambers 23 formed by the upper andlower fixed scrolls 33 and 34 and the swing scroll 35, the refrigerantflows from the outside to the inside of the spiral shape. Therefrigerant compressed in the compression chamber 23 between the lapportion 33 a of the upper fixed scroll 33 and the lap portion 35 a atthe upper surface of the swing scroll 35 passes through a communicationhole 35 d near the boss portions of the swing scroll 35, flows togetherwith a refrigerant compressed in the compression chamber 23 between thelap portion 34 a of the lower fixed scroll 34 and the lap portion 35 cat the lower surface of the swing scroll 35, opens the discharge valve26 near the bearing 4 b of the lower fixed scroll 34, passes through thedischarge pipe 22, and then is discharged to the outside of the sealedcontainer 20.

Between the main axis 10 and the respective scrolls 33, 34, and 35, theupper main bearing 4 a, the lower main bearing 4 b, and the swingbearing 5 are provided, respectively, as previously described above.Between the decentrated slider portion 10 a of the main axis 10 and theinner surface of the swing bearing 5 of the swing scroll 35, the slider11 is engaged. The first pivot portion disposed at the decentratedslider portion 10 a and the slide surface inside the slider 11 are inclose contact with each other through lubricating oil to constitute asliding portion. Between the inner surface of the lower main bearing 4 band the second pivot portion of the main axis 10, the sleeve 12 isengaged to be in close contact with each other through lubricating oilto constitute the sliding portion. Lubricating oil for lubricating thesesliding portions is supplied through the oil hole 10 c by driving theoil pump 18 by the rotation of the main axis 10.

The main axis 10 is provided with the balancers 13 and 14, whichmaintains the static balance and the dynamic balance of the swing scrollthat eccentrically rotates, at the upper portion of the upper fixedscroll 33 and the lower portion of the lower fixed scroll 34,respectively. A thrust surface 10 f of the main axis 10 and an axialthrust surface 33 i of the upper fixed scroll 33 support the load in theperpendicular direction including the self weight of the main axis 10.At the outer circumferential side of the lap portions 33 a and 35 abetween the upper fixed scroll 33 and the swing scroll 35, the Oldhamring 7 for suppressing the rotation of the swing scroll 35 and swingingthe swing scroll 35 as predetermined is disposed.

The seals 24 and 25 and the seal ring 36 are formed with non-metalmaterials, such as PTFE, PPS, LCP, or ceramic materials. The seal 25that slides with the bottom land 33 e of the upper fixed scroll 33 isformed with iron metal, such as cast iron, or an Al—Si alloy metal,which is the same material as that of the upper fixed scroll 33.However, the surface of the upper fixed scroll 33 including the bottomland 33 e of the upper fixed scroll 33 is subjected to coating of anyone of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., or film formationtreatment of any one of a manganese phosphate film, a molybdenumdisulfide film, etc.

The bottom land 35 e at the upper side of the panel 35 b of the swingscroll 35 that slides with the seal 24 is formed with iron metal, suchas cast iron, or an Al—Si alloy metal, which is the same material asthat of the swing scroll 35. However, the surface of the swing scroll 35including the bottom land 35 e of the swing scroll 35 is subjected tocoating of any one of DLC, DLC-Si, CrN, TiN, TiCN, WCC, VC, etc., orfilm formation treatment of any one of a manganese phosphate film, amolybdenum disulfide film, etc.

The seal ring sliding surface 33 k of the upper fixed scroll 33 thatslides with the seal ring 36 is formed with iron metal, such as castiron, or an Al—Si alloy metal, which is the same material as that of theupper fixed scroll 33. However, the surface of the upper fixed scroll 33including the seal ring sliding surface 33 k of the upper fixed scroll33 is subjected to coating of any one of DLC, DLC-Si, CrN, TiN, TiCN,WCC, VC, etc., or film formation treatment of any one of a manganesephosphate film, a molybdenum disulfide film, etc.

The seal ring sliding surface 34 k of the lower fixed scroll 34 thatslides with the other seal ring 36 is formed with iron metal, such ascast iron, or an Al—Si alloy metal, which is the same material as thatof the lower fixed scroll 34. However, the surface of the lower fixedscroll 34 including the seal ring sliding surface 34 k of the lowerfixed scroll 34 is subjected to coating of any one of DLC, DLC-Si, CrN,TiN, TiCN, WCC, VC, etc., or film formation treatment of any one of amanganese phosphate film, a molybdenum disulfide film, etc.

The sliding portions of the scroll compressor according to Embodiment 7are shown in Table 7. In Table 7, the name of each of the two components(Component 1, Component 2) that constitute the sliding portions and basematerials of the components are shown and performing the surfacetreatment (represented as coating) or replacement to ceramic materialsor resins described above to the components is clearly shown by theasterisk (*).

TABLE 7 Sliding portion Examples Name Portion Base material CoatingCeramic Resin Component 1 Upper fixed Tooth side surface Iron base•Aluminum base * * scroll Bottom land Iron base •Aluminum base * * Axialthrust surface Iron base •Aluminum base * * * Upper main bearing Ironbase •Aluminum base * * * Seal ring sliding surface Iron base •Aluminumbase * * Swing scroll Upper spiral-shaped tooth side surface Iron base•Aluminum base * * Upper spiral-shaped bottom land Iron base •Aluminumbase * * Swing bearing Iron base •Aluminum base * * * Oldham groove Ironbase •Aluminum base * * * Lower spiral-shaped tooth side surface Ironbase •Aluminum base * * Lower spiral-shaped bottom land Iron base•Aluminum base * * Lower spiral-shaped tooth crest Iron base •Aluminumbase * * Lower fixed Tooth side surface Iron base •Aluminum base * *scroll Tooth crest Iron base •Aluminum base * * Bottom land Iron base•Aluminum base * * Oldham groove Iron base •Aluminum base * * * Lowermain bearing Iron base •Aluminum base * * * Seal ring sliding surfaceIron base •Aluminum base * * Oldham ring Key portion Iron base •Aluminumbase * * * Key portion Iron base •Aluminum base * * * Slider Outercircumference Iron base •Aluminum base * * Slide surface Iron base•Aluminum base * * Sleeve Outer circumference Iron base •Aluminumbase * * Inner circumference Iron base •Aluminum base * * Main axisOuter circumference Iron base •Aluminum base * * Thrust surface Ironbase •Aluminum base * * First pivot portion Iron base •Aluminum base * *Second pivot portion Iron base •Aluminum base * * Component 2 Swingscroll Upper spiral-shaped tooth side surface Iron base •Aluminumbase * * Seal Sliding surface Resin (PPS, LCP, etc.) Main axis Thrustsurface Iron base •Aluminum base * * Main axis Outer circumference Ironbase •Aluminum base * * Seal ring Sliding surface Resin (PPS, LCP, etc.)Upper fixed Tooth side surface Iron base •Aluminum base * * scroll SealSliding surface Resin (PPS, LCP, etc.) Slider Outer circumference Ironbase •Aluminum base * * Oldham ring Key portion Iron base •Aluminumbase * * * Lower fixed Tooth side surface Iron base •Aluminum base * *scroll Lower fixed Tooth crest Iron base •Aluminum base * * scroll Lowerfixed Bottom land Iron base •Aluminum base * * scroll Swing scroll Lowerspiral-shaped tooth side surface Iron base •Aluminum base * * Swingscroll Lower spiral-shaped bottom land Iron base •Aluminum base * *Swing scroll Lower spiral-shaped tooth crest Iron base •Aluminumbase * * Oldham ring Key portion Iron base •Aluminum base * * * SleeveOuter circumference Iron base •Aluminum base * * Seal ring Slidingsurface Resin (PPS, LCP, etc.) Swing scroll Oldham groove Iron base•Aluminum base * * * Lower fixed Oldham groove Iron base •Aluminumbase * * * scroll Swing scroll Swing bearing Iron base •Aluminumbase * * * Main axis First pivot portion Iron base •Aluminum base * *Lower fixed Lower main bearing Iron base •Aluminum base * * * scrollMain axis Second pivot portion Iron base •Aluminum base * * Upper fixedUpper main bearing Iron base •Aluminum base * * * scroll Upper fixedAxial thrust surface Iron base •Aluminum base * * * scroll Slider Slidesurface Iron base •Aluminum base * * Sleeve Inner circumference Ironbase •Aluminum base * *

The scroll compressor according to Embodiment 7 also uses, as arefrigerant, the refrigerant which is a halogenated hydrocarbon or ahydrocarbon each having a carbon double bond in the composition thereofor a mixture containing thereof. However, the sliding surfaces of thesliding portions, whose temperature is likely to become high, aresubjected to coating, film formation, or replacement to non-metalmaterials, so that the iron or aluminum metal that can serve as a metalcatalyst that promotes the chemical reaction of the refrigerant is notdirectly exposed to the sliding surfaces of the sliding portions.Therefore, the decomposition or polymerization of the refrigerant issuppressed, and thus the generation of sludge is suppressed to suppresstroubles of the compressor or blocking in a refrigeration circuit, whichallows obtaining reliability over a long period of time of thecompressor.

Next, the operation of the scroll compressor will be described. When theelectric motor rotor 8 is driven by the application of a voltage to theelectric motor stator, the main axis 10 rotates around the axial center.During the operation, the decentrated slider portion 10 a of the mainaxis 10 revolves relative to the axial center (rotation center). By therevolution movement, the swing scroll 35 with which the decentratedslider portion 10 a is engaged slides relative to the upper and lowerfixed scrolls 33 and 34. Due to the Oldham ring 7 that suppresses therotation of the swing scroll 35, the swing scroll 35 can swing withoutrotating. Then, at the upper and lower surfaces of the panel 35 b of theswing scroll 35, the respective contact portions of the respective lapportions 35 a, 33 a, 35 c, and 34 a move toward the center and eachcompression chamber 23 moves toward the center while reducing thecapacity. By the operation, a refrigerant flows into the compressionchamber 23 from the inhalation pipe 21 through the inhalation port, andis compressed, reaches the central portion of the lap portions 35 a, 33a, 35 c, and 34 a, and then is discharged from the discharge pipe 22through the discharge port 34 m.

The scroll compressor of Embodiment 7 has the spiral-shaped lap portions35 a and 35 c at both the upper and lower sides of the disk-like panel35 b of the swing scroll 35 and can offset the thrust force generatingin the swing scroll 35. This eliminates the necessity of having a thrustbearing structure. The swing scroll 35 is lightly pressed against thelower fixed scroll 34 due to the back pressure of the seal 25 disposedat the tooth crest of the upper lap portion of the swing scroll 35, thetooth crest of the lower lap portion 35 c of the swing scroll 35 and thebottom land 34 e of the lower fixed scroll 34 are brought into moderatecontact with each other, and the bottom land 35 e at the lower side ofthe swing scroll 35 and the tooth crest of the lap portion 34 a of thefixed scroll 34 are brought into moderate contact with each other. Thus,the leak from the lap portion top end can be reduced without using aseal for the tooth crest of the lower lap portion of the swing scroll35. Thus, a high-reliability and high-performance scroll compressor canbe obtained at a lower cost.

The term “coating” used in Tables 1 to 7 shown in Embodiments 1 to 7refers to performing coating or film formation treatment to the slidingsurfaces with materials described in each Embodiment. The term“ceramics” refers to constituting at least the sliding surfaces withceramic materials, such as silicon carbide, zirconium dioxide, orsilicon nitride. The term “PTFE” refers to constituting at least thesliding surfaces with non-metal materials, such as resin, such aspolytetrafluoroethylene, or carbon.

Even when not all but some of the sliding portions shown in Tables 1 to7 are treated so that the iron metal or aluminum metal is not directlyexposed, the occurrence of the decomposition or polymerization by thechemical reaction of the refrigerant is reduced. Thus, the presentinvention is effective. Moreover, even when the treatment is performedto the sliding surface of only one component of the componentsconstituting the sliding portions, the present invention is effective.

REFERENCE SIGNS LIST

-   -   1 Fixed scroll,    -   1 a Fixed scroll lap portion,    -   1 b Fixed scroll panel,    -   1 d Fixed scroll lap portion side surface,    -   1 e Fixed scroll bottom land,    -   1 f Discharge port,    -   1 g Fixed scroll Oldham groove,    -   2 Swing scroll,    -   2 a Swing scroll lap portion,    -   2 b Swing scroll panel,    -   2 d Swing Scroll lap portion side surface,    -   2 e Swing scroll bottom land,    -   2 f Swing scroll Oldham groove,    -   3 Frame,    -   3 a Frame inhalation port,    -   3 f Frame Oldham groove,    -   4 Main Bearing,    -   5 Swing Bearing,    -   6 Thrust Plate,    -   6 a Sliding surface,    -   7 Oldham ring,    -   7 a, 7 b, 7 c, and 7 d Key convex portion,    -   8 Electric motor rotor,    -   9 Electric motor stator,    -   10 Main Axis,    -   10 a Decentrated slider axis,    -   10 b Pump axis,    -   10 c Oil hole,    -   10 d First pivot portion,    -   10 e Second pivot portion,    -   11 Slider,    -   12 Sleeve,    -   13, 14 Balancer,    -   15 Sub-frame,    -   15 a Bearing storage portion,    -   15 b Secondary bearing,    -   15 c Axial thrust receiver,    -   Ball Bearing,    -   18 Oil Pump,    -   19 Oil sump,    -   20 Sealed container,    -   20 a Sealed Container trunk portion,    -   20 b Sealed container lower portion,    -   20 c Sealed container upper portion,    -   21 Inhalation pipe,    -   22 Discharge pipe,    -   23 Compression chamber,    -   24, 25 Seal,    -   26 Discharge valve,    -   27 Slider plate,    -   29 First frame,    -   30 Second frame

The invention claimed is:
 1. A scroll compressor, in which there areprovided an electric motor portion, a compression mechanism portionconnected to the electric motor portion, and an oil sump for lubricatingoil in a sealed container, and in which the compression mechanismportion compresses a refrigerant, wherein the refrigerant includes oneof: a mixture containing halogenated hydrocarbon having a carbon doublebond and R32, and a mixture containing halogenated hydrocarbon having acarbon double bond and R41, and a sliding surface of at least one of twocomponents constituting a sliding portion having a relation of slidingto each other in the sealed container is structured in such a way as tobe subjected to coating treatment or coating film formation treatmentwith material that does not include iron and aluminum, and that suppressdecomposition or polymerization of the refrigerant, so that an ironmetal or an aluminum metal is not directly exposed to the refrigerant.2. The scroll compressor of claim 1, wherein the compression mechanismportion includes: a fixed scroll and a swing scroll that form acompression chamber by combining spiral portions in which the spiraldirections are reverse to each other, a swing bearing provided at theside of an anti-compression chamber of the swing scroll, a frame thatsupports a thrust bearing surface of the swing scroll through a thrustplate, an Oldham ring including upper and lower convex portions servingas keys which are accommodated in the swing scroll and the frame toprevent rotation of the swing scroll, a main axis that transmits adriving force to the swing scroll, penetrates a main bearing provided atthe central portion of the frame, and is connected to an oil pump forsupplying the lubricating oil in the oil sump to the sliding portion, aslider rotatably stored in the swing bearing and into which the mainaxis is inserted, and a sleeve rotatably stored in the main bearing, andwherein a slider surface inside the slider is subjected to the coatingtreatment or the coating film treatment.
 3. The scroll compressor ofclaim 2, wherein a slider plate is provided between the main axis andthe slider, and the slider plate is subjected to the coating treatmentor the coating film treatment.
 4. The scroll compressor of claim 1,wherein the compression mechanism portion includes: a fixed scroll and aswing scroll that form a compression chamber by combining spiralportions in which the spiral directions are reverse to each other, anOldham ring including upper and lower convex portions serving as keyswhich are accommodated in the fixed scroll and the swing scroll toprevent rotation of the swing scroll, a swing bearing provided at theside of an anti-compression chamber of the swing scroll, a thrustbearing member provided at a thrust surface of the swing scroll, a framethat supports the thrust bearing member through a thrust plate, a mainaxis that transmits a driving force to the swing scroll, penetrates amain bearing provided at the central portion of the frame, and isconnected to an oil pump for supplying the lubricating oil in the oilsump to the sliding portion, a slider rotatably stored in the swingbearing and into which the main axis is inserted, a slider plateprovided between the main axis and the slider, and a sleeve rotatablystored in the main bearing, and wherein a slider surface inside theslider or the slider plate is subjected to the coating treatment or thecoating film treatment.
 5. The scroll compressor of claim 1, wherein thecompression mechanism portion includes: a fixed scroll and a swingscroll that form a compression chamber by combining spiral portions inwhich the spiral directions are reverse to each other, a swing bearingprovided at the side of an anti-compression chamber of the swing scroll,a thrust plate provided at a thrust surface of the swing scroll, a frameprovided with a thrust bearing member at a portion supporting the thrustplate, an Oldham ring including upper and lower convex portions servingas keys which are accommodated in the swing scroll and the frame toprevent rotation of the swing scroll, a main axis that transmits adriving force to the swing scroll, penetrates a main bearing provided atthe central portion of the frame, and is connected to an oil pump forsupplying the lubricating oil in the oil sump to each sliding portion, aslider rotatably stored in the swing bearing and into which the mainaxis is inserted, a slider plate provided between the main axis and theslider, and a sleeve rotatably stored in the main bearing, and wherein aslider surface inside the slider or the slider plate is subjected to thecoating treatment or the coating film treatment.
 6. The scrollcompressor of claim 1, wherein the compression mechanism portionincludes: a fixed scroll and a swing scroll that form a compressionchamber by combining spiral portions in which the spiral directions arereverse to each other, a swing axis pivot portion provided at the sideof an anti-compression chamber of the swing scroll, a thrust plateprovided at a thrust surface of the swing scroll, a first frame providedwith a thrust bearing member at a portion supporting the thrust plate, asecond frame disposed at a lower portion of the first frame, an Oldhamring including upper and lower convex portions serving as keys which areaccommodated in the swing scroll and the first frame to prevent rotationof the swing scroll, a main axis that transmits a driving force to theswing scroll, penetrates an upper main bearing provided at the centralportion of the first frame and a lower main bearing provided at thecentral portion of the second frame, and is connected to an oil pump forsupplying the lubricating oil in the oil sump to the sliding portion andwhose self weight is supported by a secondary thrust bearing of thesecond frame, a sleeve for accommodating the swing axis pivot portion,and a swing bearing for rotatably accommodating the sleeve in the axis.7. The scroll compressor of claim 1, wherein the compression mechanismportion includes: a fixed scroll and a swing scroll that form acompression chamber by combining spiral portions in which the spiraldirections are reverse to each other, an Oldham ring including upper andlower convex portions serving as keys which are accommodated in thefixed scroll and the swing scroll to prevent rotation of the swingscroll, a swing bearing provided at the side of an anti-compressionchamber of the swing scroll, a compliant frame that supports a thrustsurface of the swing scroll, a guide frame that slidably accommodatesthe compliant frame, and a main axis that transmits a driving force tothe swing scroll, penetrates a main bearing and an auxiliary mainbearing provided at the central portion of the compliant frame, and isconnected to an oil pump for supplying the lubricating oil in the oilsump to the sliding portion, and whose self weight is supported by anaxial thrust receiver of a sub-frame.
 8. The scroll compressor of claim1, wherein the compression mechanism portion includes: a pair of fixedscrolls in which spiral portions are disposed facing each other, a swingscroll that is provided between the pair of fixed scrolls and has spiralportions to be engaged with spiral portions of the pair of fixedscrolls, respectively, at both sides of the axis direction to form acompression chamber in cooperation with the pair of fixed scrolls, anOldham ring including upper or lower convex portions serving as keyswhich are accommodated in one of the fixed scrolls and the remainingupper or lower convex portions serving as keys which are accommodated inthe swing scroll to prevent rotation of the swing scroll, a swingbearing that penetrates the central portion of the swing scroll, anupper main bearing and a lower main bearing provided at the centralportion of each of the fixed scrolls, a main axis that penetrates theswing bearing, the upper main bearing, and the lower main bearing beingconnected to an oil pump for supplying the lubricating oil in the oilsump to the sliding portion, and whose self weight is supported by anaxial thrust surface of one of the fixed scrolls, a slider rotatablystored in the swing bearing and into which the main axis is inserted,and a sleeve rotatably stored in the lower main bearing, and wherein aslider surface inside the slider is subjected to the coating treatmentor the coating film treatment.
 9. A scroll compressor, in which thereare provided an electric motor portion, a compression mechanism portionconnected to the electric motor portion, and an oil sump for lubricatingoil in a sealed container, and in which the compression mechanismportion compresses a refrigerant, wherein the refrigerant includes oneof: a mixture containing halogenated hydrocarbon having a carbon doublebond and R32, and a mixture containing halogenated hydrocarbon having acarbon double bond and R41, and a sliding surface of at least one of twocomponents constituting a sliding portion having a relation of slidingto each other in the sealed container is structured in such a way thatthe sliding surface of at least one of two components that constitutethe sliding portion is formed with a ceramic material or resin, so thatan iron metal or an aluminum metal is not directly exposed to therefrigerant.
 10. The scroll compressor of claim 9, wherein thecompression mechanism portion includes: a fixed scroll and a swingscroll that form a compression chamber by combining spiral portions inwhich the spiral directions are reverse to each other, a swing bearingprovided at the side of an anti-compression chamber of the swing scroll,a frame that supports a thrust bearing surface of the swing scrollthrough a thrust plate, an Oldham ring including upper and lower convexportions serving as keys which are accommodated in the swing scroll andthe frame to prevent rotation of the swing scroll, a main axis thattransmits a driving force to the swing scroll, penetrates a main bearingprovided at the central portion of the frame, and is connected to an oilpump for supplying the lubricating oil in the oil sump to the slidingportion, a slider rotatably stored in the swing bearing and into whichthe main axis is inserted, and a sleeve rotatably stored in the mainbearing, and wherein a slider surface inside the slider is formed withthe ceramic material or the resin.
 11. The scroll compressor of claim10, wherein a slider plate is provided between the main axis and theslider, and a slider surface of the slider plate is formed with theceramic material or the resin.
 12. The scroll compressor of claim 9,wherein the compression mechanism portion includes: a fixed scroll and aswing scroll that form a compression chamber by combining spiralportions in which the spiral directions are reverse to each other, anOldham ring including upper and lower convex portions serving as keyswhich are accommodated in the fixed scroll and the swing scroll toprevent rotation of the swing scroll, a swing bearing provided at theside of an anti-compression chamber of the swing scroll, a thrustbearing member provided at a thrust surface of the swing scroll, a framethat supports the thrust bearing member through a thrust plate, a mainaxis that transmits a driving force to the swing scroll, penetrates amain bearing provided at the central portion of the frame, and isconnected to an oil pump for supplying the lubricating oil in the oilsump to the sliding portion, a slider rotatably stored in the swingbearing and into which the main axis is inserted, a slider plateprovided between the main axis and the slider, and a sleeve rotatablystored in the main bearing, and wherein a slider surface inside theslider or a slider surface of the slider plate is formed with theceramic material or the resin.
 13. The scroll compressor of claim 9,wherein the compression mechanism portion includes: a fixed scroll and aswing scroll that form a compression chamber by combining spiralportions in which the spiral directions are reverse to each other, aswing bearing provided at the side of an anti-compression chamber of theswing scroll, a thrust plate provided at a thrust surface of the swingscroll, a frame provided with a thrust bearing member at a portionsupporting the thrust plate, an Oldham ring including upper and lowerconvex portions serving as keys which are accommodated in the swingscroll and the frame to prevent rotation of the swing scroll, a mainaxis that transmits a driving force to the swing scroll, penetrates amain bearing provided at the central portion of the frame, and isconnected to an oil pump for supplying the lubricating oil in the oilsump to each sliding portion, a slider rotatably stored in the swingbearing and into which the main axis is inserted, a slider plateprovided between the main axis and the slider, and a sleeve rotatablystored in the main bearing, and wherein a slider surface inside theslider or a slider surface of the slider plate is formed with theceramic material or the resin.
 14. The scroll compressor of claim 9,wherein the compression mechanism portion includes: a fixed scroll and aswing scroll that form a compression chamber by combining spiralportions in which the spiral directions are reverse to each other, aswing axis pivot portion provided at the side of an anti-compressionchamber of the swing scroll, a thrust plate provided at a thrust surfaceof the swing scroll, a first frame provided with a thrust bearing memberat a portion supporting the thrust plate, a second frame disposed at alower portion of the first frame, an Oldham ring including upper andlower convex portions serving as keys which are accommodated in theswing scroll and the first frame to prevent rotation of the swingscroll, a main axis that transmits a driving force to the swing scroll,penetrates an upper main bearing provided at the central portion of thefirst frame and a lower main bearing provided at the central portion ofthe second frame, and is connected to an oil pump for supplying thelubricating oil in the oil sump to the sliding portion and whose selfweight is supported by a secondary thrust bearing of the second frame, asleeve for accommodating the swing axis pivot portion, and a swingbearing for rotatably accommodating the sleeve in the axis.
 15. Thescroll compressor of claim 9, wherein the compression mechanism portionincludes: a fixed scroll and a swing scroll that form a compressionchamber by combining spiral portions in which the spiral directions arereverse to each other, an Oldham ring including upper and lower convexportions serving as keys which are accommodated in the fixed scroll andthe swing scroll to prevent rotation of the swing scroll, a swingbearing provided at the side of an anti-compression chamber of the swingscroll, a compliant frame that supports a thrust surface of the swingscroll, a guide frame that slidably accommodates the compliant frame,and a main axis that transmits a driving force to the swing scroll,penetrates a main bearing and an auxiliary main bearing provided at thecentral portion of the compliant frame, and is connected to an oil pumpfor supplying the lubricating oil in the oil sump to the slidingportion, and whose self weight is supported by an axial thrust receiverof a sub-frame.
 16. The scroll compressor of claim 9, wherein thecompression mechanism portion includes: a pair of fixed scrolls in whichspiral portions are disposed facing each other, a swing scroll that isprovided between the pair of fixed scrolls and has spiral portions to beengaged with spiral portions of the pair of fixed scrolls, respectively,at both sides of the axis direction to form a compression chamber incooperation with the pair of fixed scrolls, an Oldham ring includingupper or lower convex portions serving as keys which are accommodated inone of the fixed scrolls and the remaining upper or lower convexportions serving as keys which are accommodated in the swing scroll toprevent rotation of the swing scroll, a swing bearing that penetratesthe central portion of the swing scroll, an upper main bearing and alower main bearing provided at the central portion of each of the fixedscrolls, a main axis that penetrates the swing bearing, the upper mainbearing, and the lower main bearing being connected to an oil pump forsupplying the lubricating oil in the oil sump to the sliding portion,and whose self weight is supported by an axial thrust surface of one ofthe fixed scrolls, a slider rotatably stored in the swing bearing andinto which the main axis is inserted, and a sleeve rotatably stored inthe lower main bearing, and wherein a slider surface inside the slideris formed with the ceramic material or the resin.